Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly or indirectly secured to the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element. The terms "upper", "lower", "left", "right", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description, but do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the patent. The terms "first", "second" and "first" are used merely for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "plurality" is two or more unless specifically limited otherwise.
In order to explain the technical solution of the present invention, the following detailed description is made with reference to the specific drawings and examples.
FIG. 1 is a schematic front view of an electronic device according to one embodiment of the invention. The electronic device 10 includes a housing 105, a display 106 disposed on the front surface, and a top sensor, wherein the top sensor includes a light emitting module 101, a camera 102, a light receiving module 103, and may further include a sensor 104 such as a speaker, an ambient light/proximity sensor, and the like. The Display screen 106 may be a plasma Display screen, a Liquid Crystal Display (LCD), a Light-Emitting Diode (LED) Display screen, an Organic Light-Emitting Diode (OLED) Display screen, or the like, and is used for displaying application images, supplementary lighting, or the like, and may also be any other Display screen according to actual needs. The display screen 106 may also include a touch function, for example, a capacitive touch electrode is disposed in the display screen 106 to serve as an input device for human-computer interaction.
The plurality of sensors may be disposed on the top, at other locations, or dispersed at different locations of the electronic device. In some embodiments, the sensor may also be disposed on the back of the electronic device.
The sensor is used for sending or receiving information outside the electronic equipment, such as illumination, sound and the like. For example, the camera 102 may be a visible light camera (color camera or grayscale camera) for capturing an image of an external object, the speaker is configured to convert an electrical signal into a sound signal and send the sound signal to the outside, the ambient light sensor is configured to obtain intensity information of an external ambient light, the proximity sensor is configured to detect whether an external object is close to the electronic device, and in addition, the light emitting module 101 and the light receiving module 103 may form a depth camera module for capturing depth image information of the external object. It is understood that the type of sensor is not limited thereto, and different types of sensors may be provided in the electronic device according to actual needs, for example, in one embodiment, the sensor further includes a floodlight module and the like.
Fig. 2 is a schematic structural component diagram of the electronic device 20 according to an embodiment of the present invention. In addition to the display 106, the ambient light/proximity sensor 201, the camera 102, the depth camera 210, and other sensors shown in fig. 1, the electronic device further includes a processor 206, and a microphone 202, a radio frequency and baseband processor 203, an interface 204, a memory 205, a battery 207, a MEMS (micro electro Mechanical Systems) sensor 208, an audio device 209, and other devices connected thereto, and data transmission and signal communication can be realized between different units through circuit connection. The description is given only for the constituent structure of one embodiment, and in other embodiments, the electronic device may include fewer structures or more other constituent structures. The electronic device may be a cell phone, a computer, a game console, a tablet, a television, a wearable device, a smart watch, and the like.
The processor 206 is used for overall control of the whole electronic device, and the processor 206 may be a single processor or may include multiple processor units, such as processor units with different functions. In some embodiments, the processor 206 may also be an integrated System On Chip (SOC) including a central processing unit, on-Chip memory, a controller, a communication interface, and the like. In some embodiments, the processor 206 is an application processor, such as a mobile application processor, primarily responsible for the implementation of functions in electronic devices other than communication, e.g., text processing, image processing, and so forth.
The display screen 106 is used for displaying images under the control of the processor 206 to present applications and the like to the user, and in addition, the display screen 106 may also include a touch function, in which case the display also serves as a human-machine interaction interface for receiving input from the user.
The microphone 202 is used to receive voice information and may be used to enable voice interaction with a user.
The rf and baseband processor 203 is responsible for the communication functions of the electronic device, such as receiving and interpreting signals such as voice or text to realize information exchange between remote users.
The interface 204 is used for connecting the electronic device with the outside to further realize functions of data transmission, power transmission, and the like, and the interface 204 is controlled by a communication interface in the processor 206. The interface 204 may include a USB interface, a WIFI interface, or the like.
The memory 205 is used to store data, such as application data, system data, temporary code and data that the processor 206 stores during execution. The Memory 205 may be composed of a single Memory or a plurality of memories, and may be any Memory form available for storing data, such as a RAM (Random Access Memory), a FLASH Memory, and the like. It is understood that the memory may be a part of the electronic device, or may exist independently of the electronic device, such as a cloud memory, and the stored data may be communicated with the electronic device through the interface 204 and the like. Application programs, such as face recognition applications, are typically stored in a non-volatile readable storage medium, from which the processor will invoke the corresponding program for execution when executing the application.
An ambient light/proximity sensor 201, which may be an integrated single sensor or may be a separate ambient light sensor and proximity sensor. The ambient light sensor is used for acquiring illumination information of the current environment where the electronic equipment is located, and in one embodiment, the automatic adjustment of the screen brightness can be realized on the basis of the illumination information so as to provide more comfortable display brightness for human eyes; the proximity sensor can measure whether an object is close to the electronic equipment, and based on the measurement, some functions can be realized, such as a touch function of closing a screen when a human face is close enough to receive a call to prevent mistaken touch. In some embodiments, the proximity sensor may also quickly determine the approximate distance between the human face and the electronic device.
The battery 207 is used to provide power. The audio device 209 is used to implement voice output.
The MEMS sensor 208 is used to obtain current status information of the electronic device, such as position, orientation, acceleration, gravity, etc., and therefore the MEMS sensor 208 may include an accelerometer, a gravitometer, a gyroscope, etc. In one embodiment, the MEMS sensor 208 may be used to activate some face recognition applications, such as when a user picks up the electronic device, the MEMS sensor 208 may capture the change and transmit the change to the processor 206, and the processor 206 invokes a face recognition application program in memory to perform the face recognition application.
The camera 102 is used to capture images, and in some applications, such as a self-timer application, the processor controls the camera 102 to capture images and transmit the images to the display for display. In some embodiments, such as an unlocking program based on face recognition, when the unlocking program is activated, the camera captures an image, the processor processes the image, including face detection and recognition, and performs an unlocking task according to the recognition result. The camera 102 may be a single camera or a plurality of cameras; in some embodiments, the camera 102 may include an RGB camera for collecting visible light information, a grayscale camera, an infrared camera for collecting invisible light information, an ultraviolet camera, and the like; in some embodiments, the camera 102 may include a light field camera, a wide angle camera, a tele camera, and the like.
The camera 102 may be disposed at any position of the electronic device, such as a top end or a bottom end of a front surface (the same surface as the display), a rear surface, and the like, in the embodiment shown in fig. 1, the camera 102 is disposed on the front surface of the electronic device for capturing a face image of the user; a camera 102 is also provided on the rear surface for taking pictures of the scene, etc. In one embodiment, the cameras 102 are positioned on the front and rear surfaces, which may capture images independently or may be controlled by the processor 206 to capture images simultaneously; in some embodiments, the camera 102 may also be part of the depth camera 210, such as a light receiving module in the depth camera 210 or a color camera, or the like.
The depth camera 210 includes a light emitting module 101 and a light receiving module 103 respectively responsible for signal transmission and reception of the depth camera, and the depth camera may further include a depth calculation processor for processing the received signals to obtain depth image information, and the depth calculation processor may be a dedicated processor, such as an ASIC chip, or a processor 206 in an electronic device. For example, for a structured light depth camera, the light emitting module 101 and the light receiving module 103 may be an infrared laser speckle pattern projector and an infrared camera corresponding thereto, respectively, the infrared laser speckle pattern projector is configured to emit a preset speckle pattern with a specific wavelength to a surface of a spatial object, the preset speckle pattern is reflected by the surface of the object and then imaged in the infrared camera, so that the infrared camera may obtain an infrared speckle image modulated by the object, and further, the infrared speckle image is calculated by the depth calculation processor to generate a corresponding depth image. Generally, the light source in the projector may be near infrared light source with wavelength of 850nm, 940nm, etc., and the kind of light source may include edge emitting laser, vertical cavity surface laser, or corresponding light source array, etc. The distribution of the spots in the predetermined spot pattern is generally randomly distributed to achieve the irrelevance of the sub-regions along a certain direction or a plurality of directions, that is, any one of the sub-regions selected along a certain direction meets a higher uniqueness requirement. Optionally, in some embodiments, the light emitting module 101 may also be composed of a light source such as an LED or a laser capable of emitting visible light or ultraviolet light, and configured to emit a structured light pattern such as stripes, speckles, and two-dimensional codes.
In some embodiments, the depth camera may also be a Time of Flight (TOF) based depth camera, a binocular depth camera, or the like. For a TOF depth camera, the light emitting module is configured to emit a pulse light beam or a modulated (e.g., amplitude modulated) continuous wave light beam, and the light receiving module receives the light beam reflected by the object, and then the processor circuit calculates a time interval between the emission and the reception of the light beam to further calculate depth information of the object. For the binocular depth camera, one is an active binocular depth camera which comprises a light emitting module and two light receiving modules, wherein the light emitting module projects a structured light image to an object, the two light receiving modules respectively acquire two structured light images, and a processor directly utilizes the two structured light images to calculate the depth image; the other is binocular, the light emitting module can be regarded as the other light receiving module at the moment, the two light receiving modules collect two images, and the processor directly utilizes the two images to calculate the depth image. In the following, the idea of the present invention will be described by taking a structured light depth camera as an example, and it is understood that the corresponding inventive content can also be applied to other kinds of depth cameras.
Returning to fig. 1, in order to increase the screen occupation ratio of the electronic device as much as possible, the sensor is disposed on the back of the display screen, the area of the display screen 106 corresponding to the sensor can still display the content as normal as other areas, and the sensor can penetrate through the display screen to transmit or receive signals, such as floodlight illumination, structured light projection, image acquisition, and the like. Compared with the prior art, the invention not only avoids the defect of poor reliability of the lifting structure, but also avoids the defect of poor experience brought by the special-shaped screen. It can be appreciated that the sensor is disposed on the back of the display screen 106, which is not only beneficial to improving the screen occupation ratio, but also can solve other problems, such as poor experience caused by the fact that the gaze direction of the human eyes faces the screen instead of the camera during the video call. Thus, fig. 1 only schematically shows a front view of an electronic device, and the shape, screen ratio, etc. of the electronic device may also be in other forms, such as a circle, an ellipse, a prism, etc.
However, placing the sensor (optical modules, such as light emitting module, light receiving module, camera, etc., will be described below) on the back of the display screen faces some problems, such as how to hide the sensor to provide a perfect full-screen experience for the user; for example, how to overcome the effect of the display screen on light emission and light reception (including the effect on beam amplitude and phase). The optical module is used for receiving or emitting light beams with specified wavelength or wavelength region, and the optical module is divided into a visible light optical module and a non-visible light optical module in the invention, wherein the visible light optical module is used for emitting or receiving visible light beams, and the visible non-visible light optical module is used for emitting or receiving non-visible light beams.
Fig. 3 is a schematic structural diagram of an off-screen optical system according to a first embodiment of the present invention, where the off-screen optical system includes a display screen 31 and a light receiving module 33. The light receiving module 33 is disposed on one side (e.g., the back and the bottom of the display panel) of the display panel 31, the display panel 31 includes a plasma display panel, a transparent display panel such as an LCD, an LED, and an OLED, and the display panel includes a plurality of pixel units for displaying, such as pixel units arranged periodically in the horizontal and vertical directions. In order to make the display screen transparent so that the light beam can pass through, the display screen can be realized by reasonably designing a plurality of pixel units, for example, gaps are arranged among the pixel units or partial structures inside the pixel units are made of transparent materials, so that the display screen can reach a certain aperture opening ratio, for example, 50% aperture opening ratio and the like. In some embodiments, all structures of each pixel unit of the display screen may also be made of a transparent material, so that the transparency can be improved.
The light receiving module 33 is used for receiving the light beam 34 from the display screen 31. The light receiving module 33 includes an image sensor 331, a filter element 332, and a lens 333, wherein the image sensor 331 may be a CCD (Charge Coupled Device) or a CMOS (Complementary Metal-Oxide-Semiconductor), and the filter element 332 may be a bayer filter, an infrared filter, and the like. The light receiving module may also include other structures, such as a light field camera, a photodiode, etc. Lens 333 may be a single lens or a lens group or lens array.
Fig. 4 is a schematic structural diagram of an off-screen optical system according to a second embodiment of the present invention, in this embodiment, the off-screen optical system includes a display screen 41 and a light emitting module 43. The light emitting module 43 is disposed on one side of the display panel 41 (e.g., the back side, the lower portion, etc.) of the display panel 41, the display panel 41 is a transparent display panel, and the light receiving module 43 is disposed on one side of the display panel and can emit a light beam 44 outwards through the transparent display panel (the outwards emission is only illustrative and not limiting). In this embodiment, the light emitting module 43 includes a light source 431, a lens 432, and a diffractive optical element 433, wherein the light source 431 may be a side-emitting laser emitter, a vertical cavity surface laser emitter, an LED, or an array light source composed of a plurality of sub-light sources, such as a vertical cavity surface laser emitter array chip; the lens 432 is used to collimate or focus the light beam emitted by the light source 431, and the diffractive optical element 433 receives the light beam from the lens, diffracts the light beam, and projects a patterned light beam, such as a structured light patterned light beam (e.g., a speckle pattern, etc.). In some embodiments, the light emitting module 43 may also be a floodlight, such as a floodlight composed of a light source and a diffuser; in some embodiments, the light emitting module 43 may also be a flash lamp; in some embodiments, the light emitting module may also be a TOF camera, a light source in a proximity sensor, or the like, for emitting a pulsed or modulated light beam.
In the embodiment shown in fig. 3 and 4, in the optical system under the screen composed of the display screen and the optical module (including the light emitting module and the light receiving module), the optical filters 32 and 42 may be further disposed between the display screen and the optical module, and the optical filters 32 and 42 may be configured to reduce the transmission of visible light from one side of the display screen, so that an external user cannot directly observe the optical module behind the display screen, thereby the display screen may have integrity in appearance and improve visual aesthetics.
In one embodiment, the filter is an optical switch, such as a liquid crystal shutter (liquid crystal spatial light modulator), which is in a non-transparent state when de-energized, and light cannot pass through; when the power is on, the transparent state is kept, and light can pass through the transparent state. Therefore, the optical switch is arranged between the optical module and the display screen, and the optical module can be hidden through the arrangement of the optical switch. When the optical module works, the optical switch is set to be in a transparent state, so that light rays pass through; and optical module is during operation, sets up optical switch to opaque state, prevents light and passes through to make the user of display screen opposite side can't see the optical module who sets up at the display screen offside. The optical switch may also be made of other types of materials, such as electrochromic materials, thermochromic materials, or by optical structures that allow varying passage of light.
In one embodiment, the optical filter is a one-way see-through film, which allows external light to enter the optical module through the display screen as much as possible and prevents internal light from passing through the display screen, i.e., the transmittance of the surface of the one-way see-through film facing the optical module to visible light is less than the reflectance (e.g., 5% to 30% transmittance and 90% to 95% reflectance), and the transmittance of the surface of the one-way see-through film facing the display screen to visible light is greater than the reflectance (e.g., 60% to 95% transmittance and 5% to 30% reflectance). It should be noted that, if the optical module on one side of the display screen is a visible light receiving module (such as a color camera), the imaging quality is affected to some extent due to the influence of transmittance; if the optical module at one side of the display screen receives or transmits a non-visible light beam (taking an infrared beam as an example for description), that is, the optical module includes an infrared receiving module (such as an infrared camera), an infrared transmitting module, and the like, the corresponding one-way see-through film should be configured to have a higher transmittance for infrared light, that is, for the infrared receiving module, the surface of the one-way see-through film at the side facing the display screen needs to have a higher transmittance for infrared light, and generally needs to have a transmittance greater than a reflectance; for the infrared emission module, the surface of the one-way see-through film facing the infrared emission module has a relatively high transmittance for infrared light, and generally the transmittance is required to be greater than the reflectance, for example, the transmittance is 80% to 95%, so as to ensure the imaging or projection quality. When a half mirror film is used, it is preferable to select a half mirror film having suitable performance for different optical modules.
In one embodiment, the filter is a filter for blocking visible light and allowing only light beams in a certain non-visible wavelength interval to pass through. For example, be infrared receiving module (for example infrared camera), infrared emission module etc. to the optical module of display screen one side, adopt infrared filter can make infrared receiving module, infrared emission module can gather infrared image and launch infrared beam, and prevent that visible light from passing through, can realize hiding the purpose of optical module behind the display screen from this.
In one embodiment, the optical filter is a special optical filter, the special optical filter has a low transmittance for visible light and a high transmittance for a non-visible wavelength, for example, near infrared light, in a preferred example, the transmittance for visible light is 10% to 50%, and the transmittance for near infrared light is 60% to 99%, and ambient light passes through the special optical filter and then irradiates the optical module, and after being reflected by the optical module, the possibility of re-penetrating the special optical filter is greatly reduced, so that the effect of hiding the optical module behind the display screen is achieved.
It is to be understood that the above filters are not intended to limit the present invention, and any filter that can perform a similar function can be used in the present invention.
It will be appreciated that the filter may be a separate optical device or may be combined with an optical module or a display screen, for example, when the filter is in the form of a film, the filter may be provided in the form of a coating on the surface of the display screen or the optical device.
As shown in fig. 1, the back of the display screen 106 may include circuitry, batteries, and other devices in addition to the sensors, and to hide these devices, the filters described above may be used. Indeed, since these devices do not need to capture or project a light beam outside the display screen, it is possible to hide these devices by achieving opacity in a less costly manner, such as with opaque black or other colored polymer paints.
Fig. 5 is a schematic structural diagram of an underscreen optical system including a display screen 51, an optical filter 52, and a depth camera according to a third embodiment of the present invention. The depth camera includes a light receiving module 53 and a light emitting module 54, and a filter 52 is disposed between the depth camera and the display screen 51. In one embodiment, filter 52 is an optical switch that is turned on to allow light to pass when the depth camera is operating, such as when the depth camera is enabled to capture a depth image of a human face outside the display screen during a face recognition procedure, and is turned off to prevent light from passing when the image capture is complete to hide the depth camera. In one embodiment, the light receiving module 53 and the light emitting module 54 of the depth camera both operate in a non-visible light band, such as an infrared band, for example, the light receiving module is used for collecting light beams with a wavelength of 850nm, and the light emitting module 54 emits light beams with a wavelength of 850nm, at this time, the optical filter may adopt an infrared filter with a wavelength of 850nm, so as to allow the light beams with a wavelength of 850nm to pass through, and prevent visible light from passing through to achieve the purposes of depth imaging and hiding the depth camera.
Fig. 6 is a schematic structural diagram of an underscreen optical system including a display screen 61, an optical filter, and a depth camera according to a fourth embodiment of the present invention. The depth camera comprises a light receiving module 65, a camera 66 and a light emitting module 67, and a filter is arranged between the depth camera and the display screen 61. Generally, the light receiving module 65 and the light emitting module 67 operate in a non-visible light band for collecting depth images (infrared wavelength will be described as an example below), that is, the light receiving module 65 and the light emitting module 67 become an infrared receiving module and an infrared emitting module, respectively, and the camera 66 is a visible light receiving module, such as a visible light camera, for collecting visible light images, such as color images. The filters may equally be provided as optical switches, one-way vision films, filters, etc. However, in some embodiments, a single form of filter is often not sufficient, and it is therefore desirable to provide filters in a combination of multiple different forms. As shown in fig. 6, the filters include a first filter 62, a second filter 63 and a third filter 64 corresponding to the receiving module 65, the camera 66 and the light emitting module 67, respectively (the same concept applies to the embodiment shown in fig. 5, that is, the first filter and the third filter are separately configured for the light receiving module 53 and the light emitting module 54, respectively). The first filter 62, the second filter 63 and the third filter 64 are arranged along the direction perpendicular to the optical path of the optical module, that is, the first filter 62, the second filter 63 and the third filter 64 are independently arranged, may be arranged at intervals, or may be arranged adjacent to each other in sequence, and is determined according to the position relationship among the receiving module 65, the camera 66 and the light emitting module 67, which is not limited thereto.
In one embodiment, first filter 62, third filter 64 are infrared filters, and second filter 63 is an optical switch or a see-through film.
In one embodiment, first filter 62 is a first half-mirror film, third filter 64 is a third half-mirror film, and second filter 63 is an optical switch or a second half-mirror film. For visible light, the transmittance of the surfaces of the first, second and third one-way transmission films facing the optical module is less than the reflectance, and the transmittance of the surface of the first, second and third one-way transmission films facing the display screen 61 is greater than the reflectance; for infrared light, the transmittance of the surface of the first half mirror film facing the display screen 61 is greater than the reflectance, and the transmittance of the surface of the third half mirror film facing the light emitting module is greater than the reflectance.
In one embodiment, first filter 62, third filter 64 are optical switches and second filter 63 is an optical switch or a see-through film.
It is to be understood that the above embodiments are not intended to limit the scope of the present invention, and any reasonable filter arrangement may be used.
Fig. 7 is a schematic structural view of an underscreen optical system according to a fifth embodiment of the present invention. Unlike the embodiment shown in fig. 3-6, the optical filter between the optical module and the display screen 71 includes at least two layers. It is understood that the optical filter may include different numbers of layers, some may be a single layer, and some may be multiple layers for different optical modules. The depth camera comprises a light receiving module 74, a camera 75 and a light emitting module 76, wherein a filter is arranged between the depth camera and the display screen 71, the filter comprises a first filter 72 and a second filter 73 which are overlapped along the line direction (or the light beam direction) from the optical module to the display screen, for example, the first filter 72 is an optical switch, and the second filter 73 is a one-way perspective film.
The above embodiments show how to hide the optical module on the back of the display screen.
The display screen generally comprises a plurality of pixel units which are arranged transversely and longitudinally in a periodic manner, and the plurality of pixel units form a periodic pixel diffraction structure, so that the display screen can generate a diffraction effect on an incident light beam, and finally the projection or imaging quality is reduced.
Fig. 8 is a schematic structural diagram of an off-screen optical system according to a sixth embodiment of the present invention, where the off-screen optical system includes a display screen 81 and a light emitting module. The light emitting module includes a light source 82, a lens 83 and a first Diffractive Optical Element (DOE) 84, the lens 83 is used for collimating or focusing the light beam emitted from the light source 82, the first Diffractive Optical element 84 receives the light beam from the lens, diffracts the light beam and projects a first diffracted light beam 85, and the first diffracted light beam 85 is projected to an external space through the display screen 81. The lens 83 may be a lens group, a lens array, or the like. It should be understood that the light emitting module is not limited thereto, for example, the light emitting module may be composed of only the light source 82 and the first DOE84, or the light emitting module may also include other devices, such as a micro-lens array, etc., and in short, the light emitting module may have a corresponding structure according to actual requirements.
In the prior art, a light emitting module consisting of a light source, a lens and a DOE is used to project a patterned light beam, such as a structured light patterned light beam (e.g., a speckle pattern, a stripe pattern, a two-dimensional pattern, etc.), a flood light beam, a single-point light beam, a modulated TOF light beam, and the like. When the patterned light beam emitted by the light emission module is projected outwards through the display screen 81, diffraction can be generated due to the periodic structure of the internal pixels of the display screen 81, namely, if the light emission module in the prior art is directly arranged on one side of the display screen, the patterned light beam emitted by the light emission module can be diffracted again by the display screen, at the moment, the display screen 81 is a second diffractive optical element (second DOE), the light beam secondarily diffracted can influence the patterned light beam, such as the contrast is reduced, the noise is increased, and even the light beam after secondary diffraction completely deviates from the patterned light beam, so that great challenge is brought to the arrangement of the optical module behind the screen.
In this embodiment, the first DOE84 will no longer project a predetermined patterned beam (e.g., a predetermined speckle patterned beam), but the diffraction effects of the first DOE84 and the display screen (i.e., the second DOE)81 are considered together in the design stage to achieve: the first DOE84 projects a first diffracted beam 85 upon receiving an incident beam from a light source, and the first diffracted beam 85 projects a patterned beam 86 upon being diffracted again by the second DOE 81.
In one embodiment, the design process of the first DOE84 generally includes the following steps:
firstly, acquiring the diffraction performance of a display screen, namely a second DOE, for example, describing by using a complex amplitude transmittance function, wherein one possible detection method is that a beam of plane wave is incident into the display screen from a single angle or multiple angles, the emergent light intensity distribution is collected by using a receiving screen, and the diffraction performance of the second DOE is balanced by the light intensity distribution;
secondly, based on the diffraction performance of the display screen, i.e. the second DOE, the complex amplitude spatial distribution of the first diffracted beam 85 is obtained by the patterned beam 86 through inverse diffraction calculation;
finally, the diffraction pattern of the first DOE is calculated from the complex amplitude spatial distribution of the first diffracted beam 85 and the beam distribution before incidence on the first DOE84 via the lens 83.
It is to be understood that this design process is merely exemplary and that any other reasonable design is suitable for use with the present invention.
The first DOE84 is not limited to only a single-piece DOE, and may also be a multi-piece DOE, and the multi-piece DOE is not limited to be formed on different optical devices, for example, two sub-DOEs may be respectively generated on opposite surfaces of the same transparent optical device. The first DOE84 and the second DOE81 may not be limited to being separate devices, for example, the first DOE84 may be formed on the back surface of the display screen, i.e., the second DOE81, so that the overall integration level may be improved, and since the display screen 81 often includes a plurality of layers with different functions, the first DOE may also be integrated into a certain layer of the display screen 81, or one or several sub-DOEs of the first DOE84 may be integrated into a certain layer of the display screen 81, in order to further improve the integration level.
Fig. 9 is a schematic structural diagram of an optical system under a screen according to a seventh embodiment of the present invention, where the optical system under a screen includes a display screen 91 and a light emitting module. The light emitting module includes a light source 92, a lens 93 and a first Diffractive Optical Element (DOE)94, the lens 93 is used for collimating or focusing the light beam emitted from the light source 92, the first diffractive optical element 94 receives the light beam from the lens, diffracts the light beam and projects a patterned light beam 96, and the patterned light beam 96 is projected to an external space through the display screen 91. In contrast to fig. 8, a compensation element 95 is also provided between the first DOE94 and the display screen 91, the compensation element 95 being used to compensate for diffraction effects by the display screen (second DOE) 91.
In this embodiment, a new compensation display screen 98 is formed by the compensation element 95 and the second DOE91, and the compensation element 95 in the compensation display screen 98 is designed to complement the diffraction effect of the display screen, so as to counteract the influence of the patterned light beam projected by the light emission module by the second DOE91, that is, the equiphase plane of light emitted by the compensation display screen, which is incident to the equiphase plane, is still perpendicular to the wave vector direction of incident light. The patterned beam thus emitted by the first DOE94 is incident on the compensation display screen and projected into space as patterned beam 97. It will be appreciated that it is difficult for the compensation element 95 to completely eliminate the diffractive effect of the second DOE91, and therefore it is difficult for the patterned beam 97 to be guaranteed to be identical to the patterned beam 96, with slight differences between the two being permissible, such as slightly different in the spatial distribution of intensity.
The compensation element 95 may be configured as any optical element capable of changing the amplitude and/or phase of the Light beam, such as a DOE, a Spatial Light Modulator (SLM), and so on. When the compensation element 95 is a spatial light modulator, it may be a liquid crystal spatial light modulator, which is composed of a plurality of pixels, each of which can modulate the amplitude and/or phase of incident light by changing its properties (such as refractive index, gray scale, etc.).
Compared with the embodiment shown in fig. 8, the first DOE94 in fig. 9 is designed according to the same design concept as the DOE in the conventional light emitting module, the first DOE84 in the embodiment shown in fig. 8 has a greater difficulty in design than the conventional DOE, and the compensation element 95 in the embodiment shown in fig. 9 needs to be designed with emphasis, and in one embodiment, the design steps are as follows:
in one embodiment, the design process for the compensation element 95 generally includes the following steps:
firstly, the diffraction performance of the display screen, i.e. the second DOE91, is obtained, for example, it is described by a complex amplitude transmittance function, and one possible detection method is to use a beam of plane wave to enter the display screen from a single angle or multiple angles, the emitted light intensity distribution is collected by a receiving screen, and the diffraction performance of the second DOE91 is balanced by the light intensity distribution;
secondly, based on the diffraction performance of the display screen, i.e. the second DOE91, the complex amplitude spatial distribution of the incident beam incident on the second DOE91 is obtained by the emergent beam 97 through inverse diffraction calculation;
finally, the diffraction pattern of the compensation element 95 is calculated from the complex amplitude spatial distribution of the incident beam incident on the second DOE91 and the beam distribution of the incident beam 96 incident on the compensation element 95.
In the above steps, the incident beam 96 incident on the compensation element 95 and the emergent beam 97 have almost the same spatial distribution, and may be plane wave beams or patterned beams.
It is to be understood that this design process is merely exemplary and that any other reasonable design is suitable for use with the present invention.
When the compensation element 95 is a DOE (denoted as a third DOE95), the first DOE94 and the third DOE95 are not limited to being single-piece DOEs, and may also be formed by multiple sub-DOEs in a laminated form, and the multiple sub-DOEs are not limited to being formed on different optical devices, for example, two sub-DOEs may be respectively generated on the opposite surfaces of the same transparent optical device. The first DOE94 and the third DOE95 may not be limited to be separate devices, and two DOEs may be generated on the opposite surfaces of the same transparent optical device, as the first DOE94 and the third DOE95, respectively. The third DOE95 is not limited to being a discrete device as the second DOE91, for example, the third DOE95 may be generated on one side of the display screen (the second DOE91), so that the overall integration level may be improved, and since the display screen often includes a plurality of functionally different layers, the third DOE95 may be integrated into one of the layers in order to further improve the integration level.
The relative positions of the first DOE94, the third DOE95 and the second DOE91 are not limited to the embodiment shown in fig. 9, and the three DOEs may be designed according to actual requirements, for example, the first DOE94 and the third DOE95 may be integrated into the internal layer structure of the second DOE91, and for example, the positions of the first DOE94 and the third DOE95 may be interchanged. In any case, any structural configuration that does not depart from the spirit of the present invention is applicable to the present invention.
Fig. 10 is a schematic structural diagram of an off-screen optical system according to an eighth embodiment of the present invention, where the off-screen optical system includes a display screen 101 and a light receiving module. The light receiving module comprises an image sensor 102 and a lens 103, and a light beam 106 on the other side of the display screen 101 is incident to the lens 103 through the display screen 101 and forms an image on the image sensor 102. Due to the periodic microstructure of the picture elements inside the display screen, they diffract the incident light beam 106, thereby affecting the imaging quality. In order to reduce the diffractive effect, likewise, in the present embodiment, a compensation element 104 is further provided between the image sensor 102 and the display screen 101, and the first DOE104 is used to compensate the diffractive effect by the display screen (second DOE) 101. The first DOE104 and the second DOE101 form a new compensation display screen 105, in which the first DOE104 is designed to complement the diffraction effect of the display screen, so as to counteract the influence of the second DOE101 on the imaging quality of the optical receiving module.
The first DOE104 is not limited to only a single-piece DOE, but may also be a multi-piece DOE, and the multi-piece DOE is not limited to be formed on different optical devices, for example, two sub-DOEs may be respectively generated on opposite surfaces of the same transparent optical device. The first DOE104 and the second DOE101 may not be limited to be separate devices, for example, the first DOE104 may be generated on one side of the display screen (the second DOE101), so that the overall integration level may be improved, and since the display screen 101 often includes a plurality of layers with different functions, in order to further improve the integration level, the first DOE104 may also be integrated into a certain layer of the display screen 101, or one or several sub-DOEs of the first DOE104 may be integrated into a certain layer of the display screen 101.
In the description of the embodiments shown in fig. 8-10, only the diffraction effect is described, and the hiding of the optical module is not described, in practical designs, both diffraction effects and hiding are often considered, so in the embodiments of fig. 8 to 10, it is within the scope of the present invention to add a filter between the optical module and the display screen to realize hiding, reference may be made to the embodiments of fig. 3-7 for the embodiments herein, specific embodiments of which are not set forth in detail herein, it is understood that the components of the optical module, the optical filter and the display screen, when integrally designed and integrated, the various components may be fused to each other, such as for the underscreen light emitting module shown in figure 8, the diffractive optical element may be integrated into an inner layer of the display screen with the filter arranged between the lens and the DOE. The following examples are further illustrative.
Fig. 11 is a schematic structural diagram of an underscreen optical system including an underscreen optical system according to a ninth embodiment of the present invention. The depth camera includes a light receiving module and a light emitting module, wherein the light receiving module includes an image sensor 113 and a lens 114, and the light emitting module includes a light source 116, a lens 117, and a first DOE 118. The compensating display 111 is made up of a plurality of layers and compensating elements integrated in the layers, while the first DOE118 is also integrated in the layers. The compensation element in this embodiment includes a first sub-DOE 115 corresponding to the light-receiving module and a second sub-DOE 119 corresponding to the light-emitting module, where the first sub-DOE 115 and the second sub-DOE 119 are separately disposed, and their diffraction effects are respectively complementary to those of the display screen 111. At least one of the first sub-DOE 115 and the second sub-DOE 119 may be integrated within the display screen 111. An optical filter 112 is disposed between the light receiving module, the light emitting module and the display screen 111.
It can be understood that, when the light receiving module, the light emitting module and the display screen are combined to form the depth camera under the screen, the structural form of the light receiving module and the display screen and the structural form of the light emitting module and the display screen can be arbitrarily matched according to actual needs, and are not limited to the embodiment shown in fig. 11, for example, the structure of the light emitting module and the display screen 81 shown in fig. 8 and the structure of the light receiving module and the display screen 101 shown in fig. 10 can be combined to form the depth camera under the screen.
Returning to fig. 9 or 10, in the compensation display panel, when the compensation elements 95 and 104 are liquid crystal spatial light modulators, they have a function of modulating the amplitude and phase of an incident beam, and thus can be used not only for diffraction compensation but also as optical switches to hide the light emitting module or the light receiving module. Namely, if the front light emitting module and the light receiving module are in a non-working state, the liquid crystal spatial light modulator is adjusted to be in a non-transparent state, so that the optical module behind the screen is hidden; if the front light emitting module and the light receiving module are in the working state, the liquid crystal spatial light modulator is adjusted to be in the transparent state, and phase modulation is performed on the pixel units in the liquid crystal spatial light modulator to compensate the diffraction effect of the display screen 91 or 101 on outgoing or incoming light beams. This can greatly improve the integration of the system in terms of function and structure.
In each of the above embodiments, the optical module is disposed behind the display screen, so that the display screen can transmit light, i.e., the display screen is a transparent display screen, but the transparent display screen has a higher cost than a conventional non-transparent display screen. In order to solve the problem, the invention provides a spliced display screen scheme on the basis of the above embodiments.
FIG. 12 is a schematic diagram of an electronic device including a tiled display screen, according to one embodiment of the invention. The electronic device 12 includes a housing 125, a display 126 disposed on the front surface, and sensors, wherein the sensors include a light emitting module 121, a camera 122, a light receiving module 123, and a sensor 124 such as a speaker, an ambient light/proximity sensor, and the like. Unlike the embodiment shown in fig. 1, the display screen 126 is composed of two parts, i.e., a first display screen unit 126a and a second display screen unit 126b, and the sensor is disposed behind the first display screen unit 126a, and the first display screen unit 126a is a transparent display screen, allowing the sensor disposed behind it to receive external information or transmit information to the outside. The second display screen unit 126b is set to a different attribute than the first display screen unit 126 a.
In one embodiment, the second display screen unit 126b is a non-transparent display screen, such as a common LCD display screen or a common LED display screen, which are spliced to form a whole display screen 126.
In one embodiment, the first screen unit 126a and the second screen unit 126b are the same type of screen, such as OLED screens, except that the aperture ratio of the first screen unit 126a is greater than that of the second screen unit 126b, so that light can pass through more easily. It will be appreciated that the entire display 126 need not be formed by splicing, but rather two regions of the same display are designed and manufactured with the aperture ratio of the two regions controlled. In addition to the aperture ratio, other types of settings are possible, such as the resolution of the two regions being different, the resolution of the first display screen unit 126a being smaller than the resolution of the second display screen unit 126 b; or the two regions are made of materials with different transparencies, the overall transparency of the material in the first display screen unit 126a is higher than the overall transparency of the material in the second display screen unit 126b, and finally the transparency of the first display screen unit 126a is higher than that of the second display screen unit 126 b.
In one embodiment, the display screen 126 includes more than two display screen units, such as a first display screen unit 126a for each sensor. The shape of the first display screen unit 126a and the second display screen unit 126b is not limited to the shape shown in fig. 12, for example, the first display screen unit 126a may be circular, and the second display screen unit 126b has a circular through hole matching with the first display screen unit 126a, and the two units together form a whole display screen 126.
In one embodiment, the first display 126a is controlled independently of the second display 126b, and when the sensor behind the first display 126a is activated, the first display 126a is in the off state and the second display 126b can still display the content normally.
It can be understood that, in order to meet the requirement of the sensor to send or receive signals, the solutions of the above embodiments can be applied to the present split screen solution.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.