阅读说明：本技术 具有可电调节光学层的电子设备 (Electronic device with electrically adjustable optical layer ) 是由 J·R·威尔森 J·W·万迪克 M·S·罗杰斯 于 2019-05-30 设计创作，主要内容包括：本发明题为“具有可电调节光学层的电子设备”。本发明公开的电子设备具有可电调节光学层。显示器和其它光学元件可由外壳结构支撑。所述外壳结构可形成手持式设备外壳、头戴式外壳或用于所述电子设备的其它外壳。所述电子设备中的控制电路系统可调节所述可电调节光学层。所述控制电路系统可减少用于所述可电调节光学层的透光率以隐藏所述光学元件,可在当所述光学元件正在用于接收光或输出光时增加透光率以显示出所述光学元件,并且可取决于所述电子设备的所述操作模式以其它方式调节所述可电调节光学层,以呈现所需的一组光学特性。(The invention provides an electronic device with an electrically adjustable optical layer. The electronic device disclosed by the invention is provided with an electrically adjustable optical layer. The display and other optical elements may be supported by the housing structure. The housing structure may form a handheld device housing, a head-mounted housing, or other housing for the electronic device. Control circuitry in the electronic device may adjust the electrically adjustable optical layer. The control circuitry may reduce light transmittance for the electrically adjustable optical layer to hide the optical element, may increase light transmittance to reveal the optical element when the optical element is being used to receive or output light, and may otherwise adjust the electrically adjustable optical layer to exhibit a desired set of optical characteristics depending on the operating mode of the electronic device.)

1. An electronic device, comprising:

a head-mountable housing;

an optical element supported on a front face of the head-mountable housing;

an electrically adjustable optical layer overlapping the optical element, wherein the electrically adjustable optical layer comprises:

a transparent substrate layer; and

an adjustable light transmitting layer supported by the transparent base layer; and

control circuitry configured to adjust the adjustable light-transmissive layer between: a first state exhibiting a first amount of light transmission when the control circuitry is not using the optical element; and a second state exhibiting a second amount of light transmission when the control circuitry uses the optical element, the second amount of light transmission being greater than the first amount of light transmission.

2. The electronic device defined in claim 1 wherein the head-mountable housing has a back side that is opposite the front side and wherein the electronic device comprises:

a display system configured to present an image to an eye-box on the back surface, wherein the optical element comprises an image sensor, and wherein the adjustable light transmissive layer comprises a guest-host liquid crystal layer.

3. The electronic device of claim 2, further comprising:

a notification structure overlapped by the electrically adjustable optical layer, wherein the notification structure is visible on a front side of the transparent substrate layer when the adjustable light transmissive layer is in the second state.

4. The electronic device of claim 3, wherein the notification structure comprises a notification structure selected from the group consisting of an icon and text.

5. The electronic device of claim 1, wherein the adjustable light transmissive layer comprises an electrochromic layer.

6. The electronic device defined in claim 1 further comprising a partially reflective layer that is interposed between the transparent substrate layer and the adjustable light-transmissive layer.

7. The electronic device defined in claim 6 wherein the partially reflective layer has a reflectivity of at least 10% and less than 90%, wherein the adjustable light transmissive layer comprises a liquid crystal layer, and wherein the optical element comprises an optical element selected from the group consisting of an ambient light sensor, a proximity sensor, a digital image sensor, a light emitting diode, and a laser.

8. An electronic device, comprising:

wireless transceiver circuitry;

control circuitry coupled to the wireless transceiver circuitry;

an optical element;

an electrically adjustable optical layer overlapping the optical element, wherein the electrically adjustable optical layer comprises:

a partially reflective layer;

an adjustable light-transmissive layer, wherein the adjustable light-transmissive layer is located between the partially reflective layer and the optical element, wherein the control circuitry is configured to adjust the electrically-adjustable optical layer to increase light transmittance through the adjustable light-transmissive layer when the optical element is in use.

9. The electronic device defined in claim 8 further comprising a transparent substrate layer, wherein the partially reflective layer is between the transparent substrate layer and the adjustable light-transmissive layer.

10. The electronic device defined in claim 8 wherein the control circuitry is configured to adjust the adjustable light-transmissive layer to provide a visual notification when the optical element is in use.

11. The electronic device defined in claim 8 wherein the control circuitry is configured to alternately dim and brighten a portion of the adjustable light-transmissive layer to provide a visual notification when the optical element is in use.

12. The electronic device according to claim 8, wherein the adjustable light-transmissive layer overlaps a notification structure visible through the adjustable light-transmissive layer, while the adjustable light-transmissive layer has the light transmittance increased.

13. The electronic device defined in claim 8 further comprising a head-mounted housing that is configured to support the optical element, wherein the optical element comprises an image sensor, and wherein the adjustable light-transmissive layer comprises a guest-host liquid crystal layer.

14. The electronic device defined in claim 8 further comprising a display, wherein the optical element comprises an image sensor, and wherein the electrically adjustable optical layer overlaps the display.

15. The electronic device of claim 8, further comprising:

a head-mounted housing configured to support the optical element; and

a first display configured to present an image to an eyebox, wherein the optical element comprises a second display facing away from the eyebox.

16. An electronic device, comprising:

a head-mounted housing;

a display system supported by the head-mounted housing, the head-mounted housing configured to present visual content to an eyebox portion;

an image sensor supported by the headset housing;

an electrically adjustable optical layer overlapping the image sensor; and

control circuitry configured to adjust the electrically adjustable optical layer to exhibit a first light transmittance when the image sensor is not in use and to exhibit a second light transmittance when an image is captured using the image sensor, the second light transmittance being greater than the first light transmittance.

17. The electronic device defined in claim 16 wherein the electrically adjustable optical layer comprises an adjustable optically transmissive layer and a fixed partially reflective layer that overlaps the adjustable optically transmissive layer.

18. The electronic device of claim 17, wherein the adjustable light transmissive layer comprises a guest-host liquid crystal layer.

19. The electronic device defined in claim 16 wherein the electrically-adjustable optical layer comprises an adjustable reflective layer.

20. The electronic device defined in claim 16 wherein the electronic device has opposing front and back sides, wherein the display system is on the back side and faces the eye box, and wherein the image sensor is on the front side.

Technical Field

The present invention relates generally to electronic devices, and more particularly to electronic devices having optical elements and electrically adjustable layers.

Background

Electronic devices are sometimes provided with optical elements. The optical element may include a component, such as an image sensor (camera), a camera flash, an optical proximity sensor, or an ambient light sensor. Components such as these are typically operated through a window or portion of a display in the device housing. While optical coating structures can sometimes be provided on the windows to help blend their visual appearance with surrounding structures, the window characteristics are often inflexible, making it difficult or impossible to effectively hide the optical elements behind the window while accommodating changes in the operating environment of the device.

Disclosure of Invention

The electronic device disclosed by the invention is provided with an electrically adjustable optical layer. The display and other optical elements may be supported by the housing structure. The housing structure may form a handheld device housing, a head-mounted housing, or other housing for an electronic device. The electrically adjustable optical layer may overlap the display and other optical elements.

During operation, control circuitry in the electronic device may adjust the electrically adjustable optical layer. The control circuitry may reduce the light transmittance for the electrically adjustable optical layer to hide the optical element, may increase the light transmittance to reveal the optical element when the optical element is being used to collect data or provide an output, and may be otherwise adjusted to exhibit a desired set of optical characteristics depending on the operating mode of the electronic device.

The electrically adjustable optical layer may include an adjustable light transmissive layer, such as a guest-host liquid crystal layer, an electrochromic layer, or other adjustable light transmissive layer. The electrically adjustable optical layer may also include an adjustable layer exhibiting adjustable haze, adjustable color, and/or adjustable reflectivity.

In some configurations, an electronic device may have a housing configured to be held in a user's hand. In this type of arrangement, the front face of the device may have a display and other optical elements, and the display and/or other optical elements may be overlapped by electrically adjustable optical layers.

In other configurations, the electronic device may have a head-mountable housing with a front surface and a back surface. The back of the housing may have a display system configured to present images to the eyebox for viewing by a user. The outwardly facing front face of the housing may have a display and other optical elements that overlap the electrically adjustable optical layer.

Drawings

Fig. 1 is a schematic diagram of an exemplary electronic device with an optical element and an electrically adjustable optical layer, according to an embodiment.

Fig. 2 is a cross-sectional view of an exemplary electronic device according to an embodiment.

Fig. 3 is a cross-sectional side view of an exemplary electrically adjustable optical layer overlapping an optical element, according to an embodiment.

Fig. 4 is a front view of an exemplary electrically adjustable optical layer, according to an embodiment.

FIG. 5 is a graph illustrating how optical characteristics of an electrically-adjustable optical layer may be adjusted according to ambient light levels or other criteria, according to an embodiment.

Fig. 6 is a graph illustrating how optical characteristics of an electrically adjustable optical layer may be adjusted over time according to an embodiment.

Fig. 7 is a table illustrating how optical characteristics of an electrically-adjustable optical layer may be adjusted based on an operating mode of an electronic device, according to an embodiment.

Fig. 8, 9, 10, and 11 are cross-sectional side views of exemplary electrically adjustable optical layers according to embodiments.

Detailed Description

The electronic device may be provided with an optical element. The optical element may be mounted in an electronic device housing. The electrically adjustable optical layer may overlap the optical element. The electrically adjustable optical layer may be adjusted based on changes in the operating environment or other parameters of the electronic device. The optical properties of the adjustable, electrically adjustable optical layer include light transmittance, reflectance, absorbance, color, and haze.

The electrically adjustable optical layer may be utilized for dynamic adjustment to help adjust the appearance of the electronic device. For example, the light transmittance of the electrically-adjustable optical layer may be dynamically adjusted to allow light to pass through or to provide the electrically-adjustable optical layer with an opaque appearance or other desired appearance. In some configurations, the electrically tunable optical electrical layer may be in a partially transparent state. The electrically adjustable optical layers may be adjusted, if desired, to inform an observer of the device of the operational status of the device. For example, text, icons, and other patterns may be displayed using the electrically adjustable optical layer whenever the electronic device is using a camera or other input device.

An illustrative electronic device of the type that may be provided with electrically adjustable optical electrical layers is shown in FIG. 1. The electronic device 10 may be a computing device such as a laptop computer, a desktop computer such as a computer monitor containing an embedded computer, a tablet computer, a cellular telephone, a media player, or other handheld or portable electronic device, a smaller device such as a wrist-watch device, a hanging device, a headset or earpiece device, embedded in glasses, goggles, devices in a helmet, or other equipment worn on the head of a user (e.g., virtual reality or mixed reality devices, such as head-mounted virtual reality and/or mixed reality devices), or other wearable or miniature devices, televisions, computer displays that do not contain embedded computers, gaming devices, navigation devices, embedded systems such as systems in which electronic equipment with a display is installed in a kiosk or automobile, equipment that implements the functionality of two or more of these devices, or other electronic equipment.

As shown in FIG. 1, electronic device 10 may have control circuitry 16. Control circuitry 16 may include storage and processing circuitry to support the operation of device 10. The storage and processing circuitry may include storage devices, such as hard disk drive storage devices, non-volatile memory (e.g., flash memory or other electrically programmable read-only memory configured to form a solid state drive), volatile memory (e.g., static or dynamic random access memory), and so forth. Processing circuitry in control circuitry 16 may be used to control the operation of device 10. The processing circuitry may be based on one or more microprocessors, microcontrollers, digital signal processors, baseband processors, power management units, audio chips, application specific integrated circuits, and the like.

The device 10 may have input-output circuitry such as input-output device 12. The input-output device 12 may include: a user input device that collects user input; and an output component that provides output to a user. The device 12 may also include sensors that gather information from the environment. The communication circuitry 20 may be used to receive data for the device 10 and may be used to provide data from the device 10 to external devices. The communication circuitry 20 may include one or more antennas and associated radio-frequency transceiver circuitry. The transceiver circuitry may include wireless local area network transceiver circuitry, cellular telephone transceiver circuitry, and/or other radio frequency transceiver circuitry and may operate in any suitable frequency band (e.g., frequencies 700 + 2700MHz, 2.4-5GHz, less than 700MHz, greater than 2700GHz, etc.). If desired, the communication circuitry 20 may also include circuitry for supporting wired communication between the device 10 and external equipment.

Input-output devices 12 may include one or more displays, such as display 14. The display 14 may be a touch screen display that includes a touch sensor for collecting touch input from a user, or the display 14 may be touch insensitive. The touch sensors of display 14 may be based on an array of capacitive touch sensor electrodes, an acoustic touch sensor structure, a resistive touch device, a force-based touch sensor structure, a light-based touch sensor, or other suitable touch sensor arrangements. The display 14 may be a liquid crystal display, a light emitting diode display (e.g., an organic light emitting diode display), an electrophoretic display, a microelectromechanical systems (MEM) display, or other display. More than one display may be used in the device 10 if desired. For example, the device 10 may be a head-mounted device having a first display (or group of displays) that forms part of an inwardly facing display system for presenting content viewed by a user (e.g., the user wearing the device 10) and a second display for presenting publicly visible content to viewers other than the user. As another example, a single display that may be included in device 10 may be viewable by both a user and a nearby observer (e.g., when the display is mounted on the front face of a handheld device such as a cellular telephone).

The input-output device 12 may include an optical assembly 18. The optical element 18 may include an ambient light sensor (e.g., a color ambient light sensor configured to measure the color and intensity of ambient light by taking a light measurement with a plurality of photodetector channels, each having a corresponding color filter and photodetector to measure light in a different wavelength band), an optical proximity sensor (e.g., a sensor and light emitting device such as an infrared light emitting diode and a corresponding photodetector such as an infrared photodiode to detect when an external object illuminated by infrared light from the light emitting diode is in the nearby device 10), a visible light camera (visible light digital image sensor), an infrared light camera (infrared digital image sensor), a light emitting diode and/or laser diode (sometimes referred to as a camera flash) emitting visible light camera flash illumination, an infrared light emitting diode emitting infrared camera illumination, a light sensor configured to measure the color and intensity of ambient light by taking a light measurement with a plurality of photodetector channels, each having a, One or more laser-based light sources (e.g., an infrared laser array emitting an infrared beam, for a structured light depth sensor having a digital image sensor, such as an infrared light camera, that captures an image of an object illuminated by the beam), light emitting diodes and/or lasers and sensors that support optical data port optical communication, light emitting diodes (e.g., power on/off indicators, etc.) that serve as status indicators, and/or other optical elements.

In addition to the optical elements 18, the input-output devices 12 may include buttons, joysticks, scroll wheels, touch pads, keypads, keyboards, microphones, speakers, tone generators, vibrators, cameras, lasers, light emitting diodes and other status indicators, non-optical sensors (e.g., temperature sensors, microphones, capacitive touch sensors, force sensors, gas sensors, pressure sensors, sensors that monitor device orientation and motion, such as inertial measurement units formed by accelerometers, compasses, and/or gyroscopes), data ports, and the like. A user may provide commands through input-output device 12 to control the operation of device 10 and may receive status information and other output from device 10 using output resources of input-output device 12.

Device 10 may have one or more electrically adjustable optical devices, such as electrically adjustable optical layer 8. The layer 8 can be adjusted to operate in different modes. For example, in different modes of operation, layer 8 may exhibit different light transmission values (e.g., a high light transmission value of at least 80% or at least 90% or a low light transmission value of less than 40%, less than 20%, or less than 10%), different colors (e.g., non-neutral colors such as blue, red, green, blue-black, etc.), different neutral colors (white, black, gray, etc.), different reflectivities (e.g., a low reflectivity of less than 40%, less than 20%, or less than 10%, or a high reflectivity of greater than 60%, greater than 80%, or greater than 90%), different amounts of haze, and/or other properties that alter the appearance and/or light transmission, absorption, reflectance, color, and/or haze of layer 8. The electrically adjustable optical layer 8 may be formed from a liquid crystal device, such as a guest host liquid crystal device, a liquid crystal device with a polarizer or cholesteric liquid crystal device, an electrochromic device, a suspended particle device, an electrophoretic device, an electrowetting device, an adjustable color filter, and/or other adjustable device, having adjustable optical properties, such as haze, color, light reflectance, light absorbance, and/or light transmittance.

The device 10 may have a housing. The housing may form a laptop computer housing, a housing for a watch, a cellular telephone housing, a tablet computer housing, a housing for a wearable device such as a head-mounted device (e.g., a head-mountable housing structure for glasses, goggles, helmet, or wearable device), or other suitable device housing. Fig. 2 shows a side view of an illustrative electronic device. The exemplary device of fig. 2 has a planar configuration (e.g., for use as part of a laptop computer, tablet computer, cellular telephone, etc.). The device 10 may also form a laptop computer or other equipment. This arrangement is presented as an example. In arrangements where the device 10 is worn on the head of a user, the device 10 may have a curved housing configured to conform to the curved surface of the user's face. The curved housing may, for example, have a convex front face facing outwardly and an opposite concave rear face facing inwardly toward the head of the user. If desired, layers of glass, polymers, and/or other materials that form part of the fixed and/or adjustable components in the apparatus 10 may be used to form some or all of the housing (support structure) of the apparatus 10. In general, the housing of device 10 may have any suitable configuration.

In the embodiment of fig. 2, the device 10 has a first face F and an opposite second face R. In some arrangements, such as when the device 10 is a cellular telephone or other hand-held portable device, the first face F may sometimes be referred to as the front face of the device 10, and the second face R may sometimes be referred to as the back face R. In configurations where the device 10 is worn on the head of a user (e.g., when the device 10 is a head-mounted device), the first face F may sometimes be referred to as the front face F or outward-facing face F of the device 10, and the second face R may sometimes be referred to as the back face R or inward-facing face R of the device 10.

The components of the apparatus 10 may be supported by a support structure such as a housing 22 or other support structure. The housing 22, which may sometimes be referred to as a shell or box, may be formed of plastic, glass, ceramic, fiber composite, metal (e.g., stainless steel, aluminum, etc.), other suitable materials, or a combination of any two or more of these materials. The housing 22 may be formed using a one-piece configuration in which a portion or all of the housing 22 is machined or molded into a single structure, or the housing 68 may be formed using multiple structures (e.g., an internal frame structure, one or more structures that form an external housing surface, etc.). When device 10 is configured to be worn on a user's head, an optional housing portion 22' (e.g., a helmet sidewall or strap structure, a temple in a pair of eyeglasses, a strap for a visor or other support headgear structure, etc.) may be included in housing 22.

The device 10 may include one or more displays. For example, in a head-mounted device configuration, device 10 may include an inward-facing display system 14 '(e.g., a display and lenses or other optical elements configured to direct virtual reality and/or blended real images to the user's eyes located in eyebox 28).

The optical element 18 may be mounted on the face R and/or the face F. For example, as shown in fig. 2, the first optical element 18 may be mounted in the central region CR of the front surface F. The first optical element 18 may be, for example, a display (see, e.g., display 14 of fig. 1) or other optical element 18. The second optical element 18 (and, if desired, additional optical elements 18) may be mounted in other portions of the front face F, such as portions EG of the front face F. Electrically adjustable optical layer 8 may overlap one or more optical elements 18. If desired, the layer 8 may have independently adjustable portions (layers) formed using independently adjustable electrodes on a common material layer and/or multiple different material layers. For example, a first portion of layer 8 may overlap a component 18 in region EG, and a second portion of layer 18 may overlap a component 18 in region CR. Configurations in which separate independently adjustable optical devices overlap the respective optical elements 18 may also be used. By overlapping component 18 with layer 8, layer 8 is interposed between component 18 and a viewer (such as viewer 30 viewing apparatus 10 in direction 32). The observer 30 may be a user of the apparatus 10 or may be another individual.

During operation, the layer 8 may be adjusted to facilitate operation of the assembly 18 to provide information to a viewer 30 (e.g., a user of the device 10 or another person) or the like. For example, layer 8 may be adjusted to present a dark or other hazy appearance when it is desired to block assembly 18 from view by viewer 30, or layer 8 may be adjusted to present a clear appearance when it is desired to allow light to pass through layer 8 so that optical elements 18 may emit and/or receive light. Arrangements in which the haze, color, reflectivity, and/or other optical properties of layer 8 are adjusted may also be used.

The housing 22 can be used to support the optical element 18 and the layer 8 (e.g., the optical element 18 can be positioned between the layer 8 and the housing 22). In general, any suitable number of optical elements 18 may be present in device 10 (e.g., at least 1, at least 2, at least 3, at least 4, at least 5, at least 10, at least 20, less than 25, less than 15, less than 7, etc.), and these components may be mounted on face F, face R, sidewall portions, straps, and other support portions of device 10 (e.g., housing portion 22') and/or other portions of device 10. There may be fewer layers 8 than optical elements 18, the number of individual tunable layers 8 may equal the number of optical elements 18, or there may be more layers 8 than optical elements 18. Each layer 8 may have one or more individually adjustable regions.

An illustrative electrically adjustable optical layer 8 is shown in fig. 3. As shown in FIG. 3, the electro-optical layer 8 may cover the optical element 18 and may be mounted on the F-side of the device 10, if desired. The electro-optic layer 8 may include one or more sub-layers, such as layer 34. Layer 34 may exhibit fixed and/or electrically adjustable optical properties. The optical element 18 may emit and/or receive light during operation. If desired, structures that do not emit and/or do not receive light, such as structure 18', may also be overlapped by the same layer 8 as the assembly 18 and/or a different layer 8. The structure 18' may be formed of metal, polymer (e.g., colored ink), glass, and/or other materials, and may have the shape of an icon, text, or other shape. By placing layer 8 in an opaque state, the shape of structure 18 'may be hidden by layer 8, and by placing layer 8 in a transparent state (as an example), the shape of structure 18' may be shown from view (e.g., an icon formed by structure 18', textual content of structure 18', etc.). Because the structure 18 'may be configured to communicate alert messages to viewers (e.g., status indications, warnings, or other visual notifications), the structure 18' may sometimes be referred to as a notification structure or static notification structure, an icon, text, a notification, or the like.

One or more of the layers 8 of the layer 34 may be electrically adjustable. Layer 34 may also include a non-adjustable layer. For example, one or more of the layers 34 may exhibit a desired fixed amount of light transmittance, reflectance, absorbance, haze, and color shift for light passing through the layer. The fixed color shifting layer may be formed from a coating of a polymer or other material containing a colorant, such as a dye or pigment. The fixed haze layer may be formed from a textured layer or a layer incorporating light scattering particles. The layer with a fixed reflectivity, light transmittance and light absorption may be formed from a thin metal layer or one or more other layers of materials. Thin film interference filters formed from thin film stacks (e.g., dielectric stacks having alternating higher and lower refractive index values) can also be used as optical layers having fixed optical properties. In some arrangements, a partially reflective layer (e.g., a partially reflective layer such as a thin metal layer or a thin film interference filter having a light transmittance of at least 10%, at least 20%, or at least 35%, and less than 65%, less than 70%, less than 80%, or less than 90%) can be formed.

Layer 34 may include one or more dynamically adjustable light transmissive layers, such as a guest-host liquid crystal device that exhibits electrically adjustable light transmittance (as well as light absorption and reflectance). The layers can, for example, be adjusted to exhibit a transparent state (e.g., a light transmission of at least 75%, at least 90%, or other suitable high light transmission value), an opaque state (e.g., a light transmission of less than 25%, less than 10%, or other suitable low light transmission value), and can be adjusted to exhibit a desired intermediate light transmission value. Additional embodiments of electrically adjustable optical layers having adjustable light transmittance (as well as adjustable reflectivity and absorptivity) and which may sometimes be referred to as light modulator layers or adjustable light transmissive layers include liquid crystal devices with polarizers, micro-electromechanical system (MEM) light modulators, cholesteric liquid crystal layers, switchable metal hydride films (e.g., adjustable magnesium hydride mirror structures), suspended particle devices, electrochromic light modulation devices, or other suitable light modulator layers for adjusting light transmittance.

Layer 34 may also include one or more electrically tunable layers that exhibit a tunable amount of reflectivity, such as cholesteric liquid crystal devices or other tunable mirror structures. If desired, the layer 34 may include one or more adjustable haze layers, such as a polymer dispersed liquid crystal layer, which is adjustable between low haze and high haze. In the polymer dispersed liquid crystal layer, a polymer layer whose gap is filled with a liquid crystal material may be sandwiched between conductive transparent electrodes on the respective first and second transparent substrates. When no electric field is applied to the electrodes, the liquid crystals in the voids are randomly oriented and exhibit a refractive index difference with the surrounding polymer layer. This causes the liquid crystal material of the void to produce a relatively large amount of haze that scatters the light that is passing through the layer. When an electric field is applied to the electrodes by the control circuitry 16, the liquid crystals of the liquid crystal material in the voids become aligned so that the liquid crystal material in the voids exhibits a refractive index that matches the surrounding polymer. In this configuration, the polymer dispersed liquid crystal layer exhibits low haze and high transparency. Moderate haze levels can be achieved by applying an intermediate level of electric field.

If desired, layers 34 may include one or more tunable color filters (e.g., electrically tunable color shift layers, sometimes referred to as electrically tunable color layers). During operation, the adjustable color filters may be electrically adjusted by the control circuitry 16. The tunable color filters may be tunable color-shifting filters that are adjustable to exhibit different color shifts and/or may be monochrome tunable intensity filters having a single (monochrome) color shift. For example, in one state, the tunable color filter layer may be transparent and may not impart any color shift to light passing through the filter. In another state, the tunable color filter may be yellow. In another state, the color filter may be pink. If desired, the filter may have a monochromatic appearance (e.g., the filter may be a monochromatic tunable filter, such as a yellow tunable filter that can be tuned continuously or in a stepwise manner to exhibit an appearance ranging from clear to light yellow to strong yellow). The color and/or intensity (saturation) of the color filter may be continuously adjusted (e.g., to any color and/or any intensity in a desired color space) or may be set to one of a more limited set of different available colors or ranges of colors and/or levels of color saturation. The color filter for layer 8 may be formed by: such as liquid crystal devices (e.g., interference filters with liquid crystal layers of electrically tunable refractive index), phase change layers that are tunable based on chalcogenide materials or other materials to selectively adjust color shift, guest-host liquid crystal devices or other devices with electrically controllable absorption spectra, electro-optical devices, electrochromic layers, or any other device that displays tunable color (tunable color shift) in accordance with an applied control signal. The adjustable color filter may have electrodes (e.g., an array of individually addressable electrodes) or other structures that allow for adjustment of various areas of the color filter.

The characteristics of the electrically adjustable optical devices in layer 34 need not be mutually exclusive. For example, one of the layers 34 may be a suspended particle device. A suspended particle device includes a nanoparticle layer suspended in a liquid sandwiched between substrate layers with transparent conductive electrodes. In the absence of an applied electric field, the nanoparticles are randomly oriented and absorb light (i.e., the layer is dark and the layer has low light transmittance). When an electric field is applied, the nanoparticles align and allow light to pass through (i.e., the layer appears clear and has high light transmittance). In addition to allowing for adjustable light transmittance, the suspended particle device is also characterized by an associated adjustable haze (e.g., 6% haze and exhibiting little light absorbance when the suspended particle device is off, and 50% haze and exhibiting much light absorbance when the suspended particle device is on). In this way, the suspended particle device can be used as both an adjustable light transmission layer and an adjustable haze layer. The other layers 34 exhibit a variety of altered optical properties. For example, adjusting the electrochromic layer can adjust the color shift and light transmittance of the layer. Adjustment of the cholesteric liquid crystal layer can affect light transmittance, reflectance, and the like. In some arrangements, layer 8 may comprise a single adjustable layer (e.g., a layer that functions primarily as an adjustable light-transmissive layer). In other arrangements, the layer 8 may comprise a plurality of adjustable layers (e.g., a first layer for adjusting light transmittance, a second layer for adjusting haze, a third layer for adjusting reflectance, etc.). In general, any suitable number of tunable optical layers 34 may be included in layer 8 and may be electrically controlled by control circuitry 16. Each layer 34 may be controlled individually, or two or more layers 34 or groups of all layers 34 may be adjusted together by circuitry 16.

If desired, layer 8 may be a global layer that extends over the entire device 10 (e.g., over all faces F or all displays, optical sensors, or other optical elements 18 on device 10). The appearance of layer 8 may be adjusted to match the appearance of the surrounding portions of housing 22 and/or other structures in device 10. For example, the device 10 may have a housing structure that is black in appearance. When it is desired to visually blend the component 18 with a black structure, the adjustable layer 8 can be adjusted to exhibit a matching black appearance. As another example, layer 8 may be placed in a transparent state when high optical transparency of layer 8 is desired (e.g., to maximize light emission from component 18 through layer 8 and/or to maximize the amount of light received by component 18 through layer 8). In general, layer 8 may be adjusted to accommodate any desired operation of device 10 (e.g., changes in use of components 18, changes in ambient light levels, and other environmental changes, changes in the operational state of device 10 such as whether an image is displayed on a display of device 10, etc.).

If desired, the electrically adjustable structure of device 10 may have individually adjustable regions with associated individually adjustable electrodes. This allows the optical properties of the different regions to be adjusted independently. As an example, a light modulator device may have an array of electrodes or other structures that allow for the adjustment of individually adjustable regions between a transparent state (light transmittance of 0% or close to 0%) and an opaque state (light transmittance of 100% or close to 100%). Each pixel of light modulator 20 may also selectively produce an intermediate level of light transmittance (e.g., a light transmittance value between 0% and 100%). Patterned electrodes such as these may also be used on the layer 34 with adjustable haze, adjustable color shift, adjustable reflectance, and/or other adjustable optical properties. If desired, separate layers 8 (e.g., separate devices formed from separate substrates) may be placed in different regions of device 10 to form separately adjustable regions, or both electrode patterning and substrate patterning may be used to allow the electrically adjustable optical layer (e.g., layer 8) to independently change the optical properties of different regions on the surface of device 10.

The electrodes and other structures in each layer 8 may be shaped to form letters, words, and other text to form icons (symbols), to form decorative patterns, to form solid areas (e.g., background areas), to form border areas (e.g., trim areas), and/or other desired areas where optical properties are to be adjusted. This allows control circuitry 16 to output visual content using different portions of layer 8. As an example, consider an illustrative portion of plane F of fig. 4. As shown in fig. 4, electrically-adjustable optical layer 8 may include an electrically-adjustable optical layer portion, such as layer 8-0 serving as a background, and may include one or more additional electrically-adjustable optical layer portions, such as layers 8-1.. 8-N, each patterned to form icons, text, solid areas, such as circular or rectangular window areas, trim, or other patterned areas within the background. The portion 8-0.. 8-N may be part of a single layer 8 or may comprise one or more separate layers.

During operation, the window area in the layer 8 may be adjusted to exhibit different amounts of light transmittance, text or icons may be illuminated and/or other adjustments may be made to the optical layer 8 when it is desired to communicate information regarding the operation of the device 10 to a viewer, such as viewer 30 (e.g., a user of the device 10 or an external viewer when the device 10 is worn on the head of the user).

Control circuitry 16 may use any suitable criteria to determine how to adjust electrically-adjustable optical layer 8. As an example, sensors may collect sensor data, control circuitry 16 may use input-output device 12 to collect information from a user or from the environment and/or control circuitry 16 may collect other information (e.g., information about image playback on one or more displays in device 10, information of which optical element 18 is being used, etc.). Based on this input, the layer 8 may be electrically adjusted.

As an embodiment, consider a scenario in which the control circuitry 16 uses an ambient light sensor to collect an ambient light measurement. As illustrated in the graph of fig. 5, control circuitry 16 may adjust an Optical Property (OP) of one or more layers 8 in device 10 based on one or more input values (operating mode, sensor data, user input command values, etc.). The exemplary input to the graph of fig. 5 corresponds to the ambient light measurement ALS. If in this embodiment the ambient light level rises, the optical property OP may decrease (see e.g. curve 40 of fig. 5) or may increase (see e.g. curve 38 of fig. 5). The optical property OP may be the light transmittance, light reflectance, light absorbance, haze, color shift, other optical properties of the layer 8 and/or a combination of two or more of these properties. Any suitable sensor readings (temperature, motion, direction, proximity, humidity, etc.), user commands, or other information obtained by control circuitry 16 may be used to adjust layer 8. The use of ambient light sensor information to adjust the optical property OP is merely illustrative.

Fig. 6 is a graph showing how control circuitry 16 may adjust optical property OP as a function of time t. In the embodiment of fig. 6, control circuitry 16 adjusts first layer 8 to exhibit a constant optical property OP (e.g., optical property OP may have a constant value V1 over time, as shown by line 42) and adjusts second layer 8 to exhibit a time-varying optical property OP as shown by line 44 (e.g., optical property OP may be adjusted between a high value, such as value V2, and a low value, such as value V4, optical property OP may be adjusted to an intermediate value (see, e.g., intermediate value V3), may be momentarily adjusted, may be pulsed (e.g., creating a flicker effect), may be rising or falling, and/or may be adjusted over time based on time-varying and/or static input from a sensor, based on user input, based on other information collected with input-output device 12, or based on meeting other criteria). Such as reaching a particular date, determining that device 10 has moved to a predetermined location (e.g., as measured using satellite navigation system circuitry), determining that the operational mode of device 10 has changed (e.g., due to user input, initiation of a media playback event, etc.). The use of the optical sensor 18 may be coordinated with the state of the layer 8, if desired. For example, the optical element 18 may be used to emit and/or receive light through the layer 8 at a time such as time tc of fig. 6 (e.g., when the layer 8 has low light absorption characteristics and high light transmittance characteristics). The layer 8 may be temporarily placed in a high transmittance state, for example, so that the camera may capture still and/or moving images, so that the ambient light sensor may obtain ambient light readings (e.g., accurate low light readings), so that the proximity sensor may acquire proximity measurements, so that the camera flash may emit flash illumination, so that the status indicator light may emit light for a visual indicator or for other suitable uses of the optical sensor 18.

Fig. 7 is an illustrative table showing how the state of layer 8 (e.g., the optical properties of layer 8) may be adjusted based on the operating mode of device 10. The different modes of operation may include (for example): whether the device 10 is worn or held by a user or placed on a table or other surface; whether the device 10 is in a low power sleep state or is actively used by the user; whether the device 10 is indoors or outdoors; whether the ambient lighting conditions are dark, medium, or bright; whether the device 10 is oriented toward a viewer, such as viewer 30; whether an image is being captured using device 10 (e.g., whether the camera is in an active state); whether the infrared optical element 18 is effective; whether a proximity sensor, an ambient light sensor, and/or a depth sensor are active; and/or whether other optical elements 18 are being used; whether a particular optical sensor 18 is to be used or is being used, etc. The different states of the adjustable electrically adjustable optical layer 8 include states exhibiting different amounts of light transmission, different amounts of light absorption, different light reflectance, different haze, different colors, and the like. In each state, one or more regions of the layer 8 may be adjusted and/or fixed and/or one or more of these regions may be time-varying adjusted.

As shown in fig. 7, for example, during operation in mode 1, control circuitry 16 may adjust layer 8 to exhibit low light transmittance. In this state, the layer 8 is dark and may prevent the optical elements 18 under the layer 8 from being viewed by the viewer 30. Optical element 18 can, for example, be a component that is not used in mode 1 and/or does not require substantial light transmission through layer 8.

In mode 2, control circuitry 16 may place layer 8 in a second state (e.g., a high transmittance state). As an example, mode 2 may correspond to a case where there is a low light level and/or where optical element 18 comprises an image sensor or other device that benefits from high light transmittance through layer 8.

In mode 3, control circuitry 16 may place layer 8 in a third state characterized by an amount of light transmission intermediate the high and low transmission states. Mode 3 may, for example, be a mode in which the optical element 18 satisfactorily operates with a slight limited amount of light, such that it is not necessary to place the layer 8 in a transparent state to allow the component 18 to function. In this manner, the level of light transmittance of layer 8 can be maintained at a level that helps to prevent viewing of assembly 18.

Mode 4 in the embodiment of fig. 7 may occur when the device 10 is used outdoors. Layer 8 may be formed on the front face of a pair of eyeglasses or other head-mounted device 10. To help blur optical element 18, the reflectivity of layer 8 may be enhanced (state 4). Layer 8 may be periodically adjusted to facilitate use of assembly 18, if desired. For example, the assembly 18 may be used once per minute (or other suitable time interval) (or other suitable time period). During periods of use of the assembly 18, the state of the layer 8 may be temporarily adjusted (e.g., transmission may increase to a high transmission level, etc.) to accommodate use of the assembly 18. During other time periods, the layer 8 may be adjusted to provide desired characteristics to the device 10 (e.g., high mirror reflectivity, particular color, low light transmittance to hide internal components in the device 10, such as overlapping optical elements 18, etc.).

Mode 4 involves using device 10 to display virtual reality content, augmented reality content, or other visual content to a user having a display (e.g., display system 10') in device 10. When the content is presented to eyebox 28, the user of device 10 may be immersed in the content. To alert a nearby person, such as observer 30, that the user is immersed in video content (or to alert observer 30 of other modes of operation, such as a mode in which a video image is being captured using an image sensor in component 18), layer 8 may be placed in a flashing state. Layer 8 may be dynamically configured to display icons if desired (e.g., by imparting light and dark regions to layer 8 in the shape of icons and/or by placing layer 8 in a transparent state such that icons of metal, ink, polymer, or other material formed under layer 8 are displayed through layer 8). Text and other modes may also be used to alert nearby people, such as the viewer 30, that the user is immersed in the video content or is recording the video. As an example, a "view video" icon or a "record video" icon, such as an informative text of "view video" or "record video" or a predetermined pattern (flashing, a particular color scheme, a haze level, etc.) with fixed and/or time-varying behavior, may also be imparted to layer 8 to serve as a notification to others that the user is viewing or recording the video. In arrangements in which the layer 8 overlaps the display 14 (e.g., the pixel array on the front face F is configured to display an image), the layer 8 may be placed in a transparent state while the display is configured to display icons, text, or other information regarding the mode of operation of the device 10.

Generally, this type of alert mechanism may be used to inform an observer of any mode of operation of device 10 (e.g., whether a visible and/or infrared camera such as a front-facing camera is being used, whether an image and/or video is being captured using an image sensor, whether device 10 is recording audio, etc.). Information regarding the status of the user of the device 10 may also be displayed. For example, the user's eye movement may be tracked by the gaze detection system, and this information may be displayed on the front face of the head mounted display by a time varying portion of layer 8 or by a display on the front face F that overlaps layer 8 (e.g., when layer 8 has been placed in a transparent configuration). In arrangements where device 10 is a cellular telephone or other handheld device, layer 8 may be used to perform such notifications for the user and others who are able to view layer 8 (e.g., on front face F or other surface of device 10). For example, when device 10 is recording audio, layer 8 may be placed in a transparent mode to show an overlapping "record audio" notification.

The optical element 18 in the central region CR may be a display if desired, and the layer 8 may be placed in a transparent state when it is desired to allow viewing of the display, and may be placed in an opaque (and/or reflective) state when it is desired to hide the display from view. The layer 8 typically has an area larger than the pixels of the display. For example, pixels in a display in device 10 may have lateral dimensions of less than 0.5mm, less than 0.1mm, less than 0.05mm, or other suitable pixel dimensions. The display may have at least 1000 pixels or may have at least 10,000 pixels (as an example). The number of independently adjustable regions of layer 8 may be less than 100, less than 10, less than 5, or other suitable number. The lateral dimension of each adjustable zone of the layer 8 may be 1-10mm, at least 1mm, at least 5mm, at least 20mm, at least 50mm, less than 200cm, less than 50cm, less than 15cm, less than 3cm, or other suitable lateral dimension. To form icons and text, layer 8 may have pre-patterned icon-shaped areas and/or text-shaped areas, may overlap icons and/or text formed from patterned metal, polymer, or other materials, or may have multiple areas that form reconfigurable indicators (e.g., form seven-segment indicators for displaying numbers, sixteen-segment indicators for displaying numeric characters, etc.).

The optical element 18 can be a forward facing optical element (the component facing the front face F of the device 10) if desired. Layer 8 may be adjusted to enhance the appearance of device 10 from outside device 10 to temporarily change state to facilitate use of components 18 (e.g., capture images, make ambient light measurements, make proximity measurements, make depth sensor measurements, allow a camera to flash, etc.). Layer 8 may also be adjusted to inform other users of the mode of operation of device 10 (e.g., to inform viewer 30 of the manner in which the user is using device 10). Adjustable text, icons, patterned areas (such as solid background areas and/or cropped areas), and/or other patterned portions of the layer 8 may be pulsed back and forth between alternating first and second appearances and/or may be otherwise spatially and/or temporally adjusted to convey information. The information displayed by layer 8 may be used to notify a user of device 10 of an incoming email, text message, voice call or other message, expiration alert, upcoming calendar entry, other reminders (e.g., location-based reminders), and the like, if desired.

Exemplary configurations for layer 8 (and apparatus 10) are shown in fig. 8, 9, 10, 11.

In the exemplary arrangement of fig. 8, the device 10 (e.g., layer 8) may have a support layer such as a base layer 50. The base layer 50 may be used as part of the housing 22 and/or may be coupled to additional support structures. For example, the base layer 50 may have a portion that forms a display overlay for a cellular telephone, tablet computer, or other computer or may form the front of a housing in a pair of glasses or other head-mounted device. The base layer 50 may be formed of a transparent material such as light-transmissive glass or polymer. Layers 52 and 54 may be formed on the inner surface of base layer 50. Layer 52 may be a partially reflective layer, such as a thin metal coating or a thin film interference filter exhibiting partial light transmission (e.g., layer 52 may be a partially reflective layer, such as a thin metal layer or a thin film interference filter, having a light transmission of at least 10%, at least 20%, or at least 35%, and less than 65%, less than 70%, less than 80%, or less than 90%).

Layer 54 may be an adjustable light transmitting layer. With this arrangement, the presence of an outwardly facing layer of the structure, such as base layer 52, may help protect layers 50 and 54 from scratches and other damage during use. The partially reflective layer 52 may be omitted or may be formed by an adjustable reflectivity layer, if desired.

If desired, the positions of layers 52 and 54 may be reversed, as shown in FIG. 9. In the exemplary arrangement of fig. 9, layer 50 is a transparent base layer, layer 54 is an adjustable light transmitting layer, and layer 52 is an optional partially reflective coating. Substrate layer 50 may face outward (on face F) and layer 52 may face inward.

In the illustrative arrangement of fig. 10, the layer 50 is an adjustable light-transmissive layer and is adjustable between a transparent state and an opaque state. Layer 56 may be a partially reflective coating. The appearance of layer 8 of fig. 10 may be clear and bright when layer 50 is in a high light transmittance state and may be dark when layer 50 is in a low light transmittance state.

Fig. 11 shows another illustrative arrangement of the layer 8. In the embodiment of fig. 11, a coating 58 (e.g., a partially reflective coating or other coating) may optionally be formed on an outer surface of the substrate layer 50 (e.g., facing outward on face F). The base layer 50 may be an electrically tunable light transmitting layer. When layer 50 is dark, the light transmittance of layer 50 will be low (e.g., less than 5%, less than 10%, or other suitable amount), and layer 8 of fig. 11 will have a mirror-like appearance (e.g., layer 8 will reflect external ambient light and will be bright). When layer 50 is tuned to exhibit high light transmission (e.g., at least 60%, at least 70%, or more), the appearance of layer 8 from the exterior of device 10 will be that of a partially reflective mirror (e.g., layer 8 will appear partially reflective), while the overlapping internal optical elements 18 will be able to operate by emitting and/or receiving light through layer 8. The use of layer 58 may also therefore help device 10 to provide an attractive appearance that is fully or partially reflective. Layer 58 may be omitted if desired.

Device 10 may include one or more substrate layers for protecting internal components (e.g., display and other optical elements 18, etc.) and/or for serving as part of housing 22. As an example, the face F may have a glass or polymer layer which extends over substantially the entire front face F. This layer may form a display overlay for a display (e.g., a display in central region CR in configurations where device 10 is a handheld or head-mounted device) or may form the front of housing 22 (e.g., when the housing is configured to form a head-mounted support structure, such as a lens for an eyepiece, a lens for glasses, a visor for a helmet, etc.). As another embodiment, the layer 8 may be formed in a window region. The window area may be circular, may be rectangular, or may have other suitable shapes. For example, the device 10 may have a glass or sapphire disk-shaped layer that serves as a window and is mounted within a metal housing structure, a polymer housing structure, or other housing structure (e.g., polymer, metal, glass, other materials, or combinations of these materials).

According to one embodiment, there is provided an electronic device including: a head-mountable housing; an optical element supported on a front face of the head-mountable housing; an electrically adjustable optical layer overlapping the optical element, the electrically adjustable optical layer including a transparent substrate layer and an adjustable light transmissive layer supported by the transparent substrate layer; and control circuitry configured to adjust the adjustable light-transmitting layer between: a first state that exhibits a first amount of light transmission when the control circuitry does not use the optical element; and a second state that exhibits a second amount of light transmission when the control circuitry uses the optical element, the second amount of light transmission being greater than the first amount of light transmission.

According to another embodiment, the head-mountable housing has a back side opposite the front side, and the electronic device includes a display system on the back side configured to present an image to the eye-rim, the optical element includes an image sensor, and the adjustable light-transmissive layer includes a guest-host liquid crystal layer.

In another embodiment, the electronic device includes a notification structure overlaid by the electrically-adjustable optical layer, the notification structure being visible on the front side of the transparent substrate layer when the adjustable light-transmissive layer is in the second state.

According to another embodiment, the notification structure includes a notification structure selected from the group consisting of an icon and text.

According to another embodiment, the adjustable light transmitting layer comprises an electrochromic layer.

According to another embodiment, an electronic device includes a partially reflective layer interposed between a transparent substrate layer and an adjustable light transmissive layer.

According to another embodiment, the partially reflective layer has a reflectivity of at least 10% and less than 90%.

According to another embodiment, the adjustable light transmitting layer comprises a liquid crystal layer.

In another embodiment, the optical element comprises an optical element selected from the group consisting of an ambient light sensor, a proximity sensor, a digital image sensor, a light emitting diode, and a laser.

According to one embodiment, there is provided an electronic device comprising: wireless transceiver circuitry; control circuitry coupled to the wireless transceiver circuitry; an optical element; an electrically adjustable optical layer overlapping the optical element, the electrically adjustable optical layer including a partially reflective layer, an adjustable light transmissive layer, the adjustable light transmissive layer being positioned between the partially reflective layer and the optical element, the control circuitry configured to adjust the electrically adjustable optical layer to increase light transmittance through the adjustable light transmissive layer when the optical element is in use.

According to another embodiment, an electronic device includes a transparent substrate layer, a partially reflective layer between the transparent substrate layer and the adjustable light transmissive layer.

According to another embodiment, the control circuitry is configured to adjust the adjustable light transmissive layer to provide the visual notification when the optical element is in use.

According to another embodiment, the control circuitry is configured to alternately dim and brighten a portion of the adjustable light-transmissive layer to provide a visual notification when the optical element is in use.

According to another embodiment, the adjustable light transmitting layer overlaps the notification structure visible through the adjustable light transmitting layer, while the adjustable light transmitting layer has an increased light transmission.

According to another embodiment, an electronic device includes a head-mountable housing configured to support an optical element.

According to another embodiment, the optical element comprises an image sensor and the adjustable light transmitting layer comprises a guest-host liquid crystal layer.

According to another embodiment, the electronic device includes a display, the optical element includes an image sensor, and the electrically adjustable optical layer overlaps the display.

According to another embodiment, the electronic device includes: a head-mountable housing configured to support an optical element; and a first display configured to present an image to the eye-box, the optical element comprising a second display facing away from the eye-box.

According to one embodiment, there is provided an electronic device comprising: a head-mounted housing; a display system supported by the head-mounted housing and configured to present visual content to the eyebox; an image sensor supported by the head-mounted housing; an electrically adjustable optical layer overlapping the image sensor; and control circuitry configured to adjust the electrically adjustable optical layer to exhibit a first light transmittance when the image sensor is not in use and to exhibit a second light transmittance when an image is captured using the image sensor, the second light transmittance being greater than the first light transmittance.

According to another embodiment, the electrically adjustable optical layer includes an adjustable light transmitting layer and a fixed partially reflective layer, the fixed partially reflective layer overlapping the adjustable light transmitting layer.

According to another embodiment the adjustable light transmitting layer comprises a guest-host liquid crystal layer.

According to another embodiment, the electrically adjustable optical layer includes an adjustable reflectivity layer.

According to another embodiment, the electronic device has opposing front and back sides, the display system is located on the back side and faces the eye-box, and the image sensor is located on the front side.

The foregoing is merely exemplary and various modifications may be made to the embodiments. The foregoing embodiments may be implemented independently or in any combination.

This patent application claims priority from U.S. application No.16/412,292 filed on day 5/14 in 2019 and provisional patent application No.62/687,183 filed on day 19/6 in 2018, the entire contents of which are incorporated herein by reference.