Image projection method and system

文档序号：340941 发布日期：2021-12-03 浏览：21次中文

阅读说明：本技术 图像投射方法和系统 (Image projection method and system ) 是由龚江涛张柳新于 2021-09-06 设计创作，主要内容包括：本申请提供了一种图像投射方法和系统,该系统包括：控制设备,以及与控制设备相连的透明全息显示屏、第一衍射光栅、第二衍射光栅及多个投射光源；透明全息显示屏的两个显示面叠加有衍射光栅；控制设备控制多个投射光源中至少一个第一投射光源向透明全息显示屏的第一显示面投射第一虚拟场景图像,向透明全息显示屏的第二显示面叠加的第二衍射光栅输出第一电调控信号,第一电调控信号用于控制第二衍射光栅中处于至少一个第一投射光源的光投射区域内的至少一个第一子光栅区处于不透光状态,使得第一子光栅区遮挡至少一个第一投射光源投射出的第一虚拟场景图像,以使得第一虚拟场景图像在第二显示面不可见。(The application provides an image projection method and system, the system comprises: the holographic display device comprises a control device, a transparent holographic display screen, a first diffraction grating, a second diffraction grating and a plurality of projection light sources, wherein the transparent holographic display screen, the first diffraction grating, the second diffraction grating and the plurality of projection light sources are connected with the control device; two display surfaces of the transparent holographic display screen are superposed with diffraction gratings; the control device controls at least one first projection light source in the plurality of projection light sources to project a first virtual scene image to a first display surface of the transparent holographic display screen, outputs a first electric control signal to a second diffraction grating superposed on a second display surface of the transparent holographic display screen, and the first electric control signal is used for controlling at least one first sub-grating region in the second diffraction grating, which is located in a light projection region of the at least one first projection light source, to be in a non-light transmission state, so that the first sub-grating region shields the first virtual scene image projected by the at least one first projection light source, and the first virtual scene image is invisible on the second display surface.)

1. An image projection system comprising: the holographic display comprises a control device, a transparent holographic display screen, a first diffraction grating, a second diffraction grating and a plurality of projection light sources;

the transparent holographic display screen, the first diffraction grating, the second diffraction grating and the projection light source are all connected with the control device;

the first diffraction grating is superposed on the first display surface of the transparent holographic display screen;

the second diffraction grating is superposed on the second display surface of the transparent holographic display screen;

the projection light source is arranged outside the transparent holographic display screen and faces the transparent holographic display screen, or is arranged in the transparent holographic display screen;

the control device controls at least one first projection light source of the plurality of projection light sources to project a first virtual scene image to a first display surface of the transparent holographic display screen, and outputs a first electrical control signal to the second diffraction grating, wherein the first electrical control signal is used for controlling at least one first sub-grating region in a light projection region of the at least one first projection light source of the second diffraction grating to be in an opaque state, so that the first sub-grating region blocks the first virtual scene image projected by the at least one first projection light source, and the first virtual scene image is invisible on the second display surface.

2. The image projection system of claim 1, further comprising: at least one eye tracker;

the human eye tracker is connected with the control equipment;

the human eye tracker collects eye positioning data of a user, and the eye positioning data of the user is used for positioning the human eye position of the user;

the control device controls at least one second projection light source in the plurality of projection light sources to project a second virtual scene image to the second display surface, and sends a second electrical control signal to the second diffraction grating, wherein the second electrical control signal is used for controlling a diffraction parameter of at least one second grating sub-region in the second diffraction grating, the diffraction parameter being located on a light propagation path from the at least one second projection light source to a human eye position of a target user, so that the second virtual scene image projected by the at least one second projection light source is only projected to the human eye of the target user through the at least one second grating sub-region, and the target user is a user located on one side of the second display surface of the transparent holographic display screen.

3. The image projection system of claim 2, further comprising: at least one interaction sensor;

the interaction sensor is arranged outside the transparent holographic display screen and connected with the control equipment; or the interaction sensor is a touch sensing unit arranged on the transparent holographic display screen and is connected with the control equipment through the transparent holographic display screen;

the interaction sensor collects input operation data input to the first display surface by a first user, and transmits the input operation data to the control equipment, wherein the first user is a user positioned on one side of the first display surface of the transparent holographic display screen;

the control device is further configured to determine, according to the input operation data, the target user selected by the first user, where the target user belongs to the at least one second user located on the second display surface side of the transparent holographic display screen.

4. The image projection system of claim 2, the first and second diffraction gratings being grating pitch adjustable diffraction gratings;

the second diffraction grating reduces the grating spacing of the first sub-grating area until the first sub-grating area is in a shading state based on the first electric control signal; and adjusting the grating pitch of the second sub-grating area based on the second electric control signal, so that the second sub-grating area has diffraction parameters required for projecting the second virtual scene image to human eyes of the target user.

5. The image projection system of claim 2, the first and second diffraction gratings being diffraction gratings with controllable diffraction coefficients;

the first electric control signal is used for controlling the diffraction coefficient of at least one first sub-grating region in the second diffraction grating to be the diffraction coefficient corresponding to the opaque state;

the second electric control signal is used for controlling the diffraction coefficient of at least one second grating sub-area in the second diffraction grating to be a target diffraction coefficient;

at least one second diffraction subregion of the second diffraction grating has the target diffraction coefficient such that the at least one second diffraction subregion is capable of projecting a second virtual scene image to the human eye of the target user.

6. An image projection method comprising:

determining a first virtual scene image to be projected to a first display surface of a transparent holographic display screen, wherein the transparent holographic display screen is provided with the first display surface and a second display surface, the first display surface is superposed with a first diffraction grating, and the second display surface is superposed with a second diffraction grating;

controlling at least one first projection light source of the plurality of projection light sources to project a first virtual scene image onto the first display surface;

outputting a first electrical control signal to the second diffraction grating, where the first electrical control signal is used to control at least one first sub-grating region in the light projection region of the at least one first projection light source in the second diffraction grating to be in an opaque state, so that the first sub-grating region blocks the first virtual scene image projected by the at least one first projection light source, and the first virtual scene image is invisible on the second display surface.

7. The method of claim 6, further comprising:

determining a target user positioned on one side of the second display surface of the transparent holographic display screen;

controlling at least one second projection light source of the plurality of projection light sources to project a second virtual scene image onto the second display surface;

and sending a second electrical control signal to the second diffraction grating, where the second electrical control signal is used to control a diffraction parameter of at least one second grating sub-region in the second diffraction grating, which is located on an optical propagation path from the at least one second projection light source to the eye position of the target user, so that a second virtual scene image projected by the at least one second projection light source is only projected to the eye of the target user through the at least one second grating sub-region.

8. The method of claim 7, the determining a target user located on a second display surface side of the transparent holographic display screen, comprising:

obtaining an input operation input by a first user on the first display surface, wherein the first user is a user positioned on one side of the first display surface of the transparent holographic display screen;

and determining a target user to which the input operation is directed based on an input position of the input operation on the first display surface and a position of at least one second user located at one side of the second display surface.

9. The method of claim 7, further comprising, prior to said sending a second electrical steering signal to said second diffraction grating:

obtaining a left eye position and a right eye position of the target user;

the controlling at least one second projection light source of the plurality of projection light sources to project a second virtual scene image onto the second display surface includes:

determining a second virtual scene image to be presented to the target user;

determining a first sub-virtual scene image to be projected to a left eye of the target user and a second sub-virtual scene image to be projected to a right eye of the target user based on the second virtual scene image;

determining at least one third projection light source required to project the first sub-virtual scene image to the left eye of the target user based on the left eye position of the target user;

determining at least one fourth projection light source required to project the second sub-virtual scene image to the right eye of the target user based on the right eye position of the target user;

controlling the at least one third projection light source to project the first sub virtual scene image to the second display surface, and controlling the at least one fourth projection light source to project the second sub virtual scene image to the second display surface, so as to present the second virtual scene image superimposed by the first sub virtual scene image and the second sub virtual scene image to the target user;

the sending of the second electrical control signal to the second diffraction grating includes:

sending a first electrical control sub-signal to the second diffraction grating, where the first electrical control sub-signal is used to control at least one third grating sub-region in the second diffraction grating, which is located on a light propagation path from the at least one third projection light source to the left eye position of the target user, to have a first diffraction parameter, so that a first sub-virtual scene image projected by the at least one third projection light source is projected only to the left eye of the target user through the at least one third grating sub-region;

and sending a second electrical control sub-signal to the second diffraction grating, where the second electrical control sub-signal is used to control at least one fourth grating sub-area in the second diffraction grating, which is located on a light propagation path from the at least one fourth projection light source to the right eye position of the target user, to have a second diffraction parameter, so that a second sub-virtual scene image projected by the at least one fourth projection light source is projected only to the right eye of the target user through the at least one fourth grating sub-area.

10. The method of claim 6, further comprising, prior to said controlling at least one first projection light source of the plurality of projection light sources to project a first virtual scene image onto the first display surface:

determining the position of the eyes of a first user on one side of the first display surface of the transparent holographic display screen;

determining, from the plurality of projection light sources, at least one first projection light source required to project a first virtual scene image to the first user;

determining at least one fifth grating sub-region of the first diffraction grating that is in a light propagation path of the at least one first projection light source to a human eye position of the first user;

before or while the controlling at least one first projection light source of the plurality of projection light sources projects a first virtual scene image onto the first display surface, the method further comprises:

and sending a third electrical control signal to the first diffraction grating, wherein the third electrical control signal is used for controlling the diffraction parameters of the at least one fifth grating sub-area, so that the first virtual scene image projected by the at least one first projection light source is diffracted to the position of the human eyes of the first user through the at least one fifth grating sub-area.

Technical Field

The present application relates to the field of display technologies, and more particularly, to an image projection method and system.

Background

The application scenarios of technologies such as mixed reality and augmented reality are increasing.

In scenes such as mixed reality, augmented reality and the like, both a virtual object and a real object exist at the same time, and virtual scenes seen by users at different positions are the same, so that the mode of presenting virtual scene images in the mixed reality scene is single, and the flexibility is poor.

Disclosure of Invention

The application provides an image projection method and system.

Wherein, an image projection system comprises: the holographic display comprises a control device, a transparent holographic display screen, a first diffraction grating, a second diffraction grating and a plurality of projection light sources;

the transparent holographic display screen, the first diffraction grating, the second diffraction grating and the projection light source are all connected with the control device;

the first diffraction grating is superposed on the first display surface of the transparent holographic display screen;

the second diffraction grating is superposed on the second display surface of the transparent holographic display screen;

In one possible implementation, the image projection system further includes: at least one eye tracker;

the human eye tracker is connected with the control equipment;

the human eye tracker collects eye positioning data of a user, and the eye positioning data of the user is used for positioning the human eye position of the user;

In yet another possible implementation, the image projection system further includes: at least one interaction sensor;

the interaction sensor is arranged outside the transparent holographic display screen and connected with the control equipment;

or the interaction sensor is a touch sensing unit arranged on the transparent holographic display screen and is connected with the control equipment through the transparent holographic display screen;

In yet another possible implementation manner, the first diffraction grating and the second diffraction grating are diffraction gratings with adjustable grating pitches;

In yet another possible implementation manner, the first diffraction grating and the second diffraction grating are diffraction gratings with controllable diffraction coefficients;

at least one second diffraction subregion of the second diffraction grating has a target diffraction coefficient such that the at least one second diffraction subregion is capable of projecting a second virtual scene image to the human eye of the target user.

In yet another aspect, the present application further provides an image projection method, including:

controlling at least one first projection light source of the plurality of projection light sources to project a first virtual scene image onto the first display surface;

In one possible implementation, the image projection method further includes:

determining a target user positioned on one side of the second display surface of the transparent holographic display screen;

controlling at least one second projection light source of the plurality of projection light sources to project a second virtual scene image onto the second display surface;

In yet another possible implementation manner, the determining a target user located on the second display surface side of the transparent holographic display screen includes:

In another possible implementation manner, before the sending the second electrical control signal to the second diffraction grating, the method further includes:

obtaining a left eye position and a right eye position of the target user;

the controlling at least one second projection light source of the plurality of projection light sources to project a second virtual scene image onto the second display surface includes:

determining a second virtual scene image to be presented to the target user;

determining at least one third projection light source required to project the first sub-virtual scene image to the left eye of the target user based on the left eye position of the target user;

determining at least one fourth projection light source required to project the second sub-virtual scene image to the right eye of the target user based on the right eye position of the target user;

controlling the at least one third projection light source to project a first sub virtual scene image to the second display surface, and controlling the at least one fourth projection light source to project a second sub virtual scene image to the second display surface, so as to present the second virtual scene image superimposed by the first sub virtual scene image and the second sub virtual scene image to the target user;

the sending of the second electrical control signal to the second diffraction grating includes:

In yet another possible implementation manner, before the controlling at least one first projection light source of the plurality of projection light sources to project a first virtual scene image onto the first display surface, the method further includes:

determining the position of the eyes of a first user on one side of the first display surface of the transparent holographic display screen;

determining, from the plurality of projection light sources, at least one first projection light source required to project a first virtual scene image to the first user;

According to the scheme, the image projection system comprises the transparent holographic display screen, and the diffraction gratings are superposed on two surfaces of the transparent holographic display screen. On the basis, the control equipment can control at least one first projection light source in the plurality of projection light sources to project the virtual scene image to the first display surface of the transparent holographic display screen, and meanwhile, the control equipment can output an electric control signal to the diffraction grating superposed on the second display surface of the transparent holographic display screen. Because the electric control signal can control at least one sub-grating region in the light projection region of the at least one first projection light source in the diffraction grating on the second display surface to be in a light-tight state, when a virtual scene image is presented on one surface of the transparent holographic display screen, a user on the other surface of the transparent holographic display screen cannot see the virtual scene image, and the diversity and the flexibility of presenting the virtual scene image are improved.

Drawings

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

FIG. 1 is a schematic diagram of an exemplary embodiment of an image projection system;

FIG. 2 is a schematic view of an application scenario of the image projection system of the present application;

FIG. 3 is a schematic diagram of another exemplary embodiment of an image projection system;

FIG. 4 is a schematic view of another application scenario of the image projection system of the present application;

fig. 5 is a schematic flowchart of an image projection method according to an embodiment of the present application;

fig. 6 is a schematic flowchart illustrating a process of projecting a second virtual scene image to a target user in the image projection method according to the embodiment of the present application;

fig. 7 is a schematic flowchart of another image projection method according to an embodiment of the present application;

fig. 8 is a schematic diagram of a composition architecture of an electronic device according to an embodiment of the present disclosure.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims, as well as in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the application described herein may be practiced otherwise than as specifically illustrated.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without inventive step, are within the scope of the present disclosure.

Referring to fig. 1, a schematic diagram of a component structure of an image projection system according to the present application is shown.

In fig. 1, the image projection system includes: a control device 101, a transparent holographic display screen 102, a first diffraction grating, a second diffraction grating, and a plurality of projection light sources 103.

The transparent holographic display screen 102, the first diffraction grating, the second diffraction grating and the projection light source 103 are all connected with the control device 101.

The image projection system may have one or more control devices, and in the case of having a plurality of control devices, the plurality of control devices may be combined into a cluster or a distributed system.

In the present application, the transparent holographic screen has two display surfaces, which may be two display planes of the transparent holographic screen. As shown in fig. 1, it appears that one display surface of the transparent holographic display screen is opposite to the other display surface of the transparent holographic display screen. For the sake of distinction, one display surface of the transparent holographic display is referred to as a first display surface, and the other display surface is referred to as a second display surface.

And diffraction gratings are superposed on the two display surfaces of the transparent holographic display screen. For the sake of convenience of distinction, the diffraction grating superimposed on the first display surface of the transparent holographic display screen is referred to as a first diffraction grating, and the diffraction grating superimposed on the second display surface of the transparent holographic display screen is referred to as a second diffraction grating.

Among them, a diffraction grating is a kind of grating. It subjects the amplitude or phase (or both) of the incident light to periodic spatial modulation by a regular structure.

The diffraction grating superposed on the display surface of the transparent holographic display screen is the diffraction grating with adjustable diffraction coefficient, so that the diffraction grating can change the light diffraction conditions of different grating areas, and the light transmission of the corresponding grating areas is changed.

Since the slits in the diffraction grating are small and dense, the diffraction grating is not visible from the user's perspective even if the diffraction grating is superimposed on the display surface of the transparent holographic display screen. Accordingly, the diffraction grating superimposed on the transparent holographic display screen is also not shown in fig. 1.

In one possible implementation, the projection light source may be a projection light source disposed outside and facing the transparent holographic display screen. And one part of the plurality of projection light sources faces the first display surface of the transparent holographic display screen, and the other part of the plurality of projection light sources faces the second display surface of the transparent holographic display screen.

For example, fig. 1 illustrates the projection light source 103 outside the transparent holographic display screen.

In yet another possible implementation, the projection light source may be a projection light source disposed within a transparent holographic display screen. If the projection light source may be an Organic light emitting semiconductor (OLED) in the transparent holographic Display screen, the projection of the image onto the transparent holographic Display screen may be achieved through an OLED light emitting point, where the projection directions of the plurality of projection light sources in the transparent holographic Display screen may also be different, for example, some of the plurality of projection light sources are mainly used for projecting the image onto the first Display surface of the transparent holographic Display screen, and another projection light source is mainly used for projecting the image onto the second Display surface of the transparent holographic Display screen.

It will be appreciated that in the case of the projection light source being an internal projection light source of a transparent holographic display, the projection light source is actually connected to the control device via the transparent holographic display.

In the application, the control device can control at least one first projection light source of the plurality of projection light sources to project a first virtual scene image to the first display surface of the transparent holographic display screen, and output a first electric control signal to the second diffraction grating.

The first electrical control signal is used for controlling at least one first sub-grating region in the second diffraction grating, which is located in the light projection region of the at least one first projection light source, to be in an opaque state, so that the first sub-grating region blocks a first virtual scene image projected by the at least one first projection light source, and the first virtual scene image is invisible on the second display surface.

The at least one first projection light source belongs to a part of the projection light sources capable of projecting the virtual image to the first display surface. For example, the control device may select, as the first projection light sources, some of the projection light sources from among the projection light sources capable of projecting the virtual image onto the first real surface as needed, and control the respective first projection light sources to project the virtual scene image to be presented on the first display surface.

For the sake of convenience of distinction, the virtual scene image to be presented on the first display surface is referred to as a first virtual scene image, and the projection light source projecting the first virtual scene image to the first display surface is referred to as a first projection light source.

The first scene image may be determined by combining a historical virtual scene image output by the transparent display screen before the current time and one or more determinations of user input operation on the first display surface, which is not limited in this respect.

It is to be understood that although the first projection light source is a projection light source whose projection direction is towards or mainly towards the first display surface of the transparent holographic display, in case at least one first projection light source projects the first virtual image towards the first display surface of the transparent holographic display, there may still be a part of the light sources of the first projection light source projected onto the second display surface of the holographic transparent holographic display. In order to improve the privacy of the virtual image display, the virtual image displayed on the first display surface of the transparent holographic display screen is invisible on the second real surface, and the light projected by the first projection light source to the user on one side of the second display surface through the second display surface needs to be shielded.

Accordingly, in order to block the light projected by the first projection light source onto the second display surface, a sub-grating region in the light projection region of the at least one first projection light source in the second diffraction grating superimposed on the second display surface needs to be determined. The sub-grating region is defined herein as a partial region of the second diffraction grating, and for the sake of convenience of distinction, the sub-grating region is referred to as a first sub-grating region in the second diffraction grating.

On the basis, the first sub-grating region can be in the opaque state by outputting a first electrical control signal for adjusting the first sub-grating region to be in the opaque state to the second diffraction grating, so that the first virtual image projected by the main first projection light source through the second display surface is shielded, and a user on one side of the second display surface cannot see the first virtual image.

It is understood that the specific form of the diffraction grating superimposed on the transparent holographic display screen in the present application may be various, and accordingly, the specific manner of adjusting the diffraction coefficient of the diffraction grating may be different.

The following is described in connection with several possible scenarios:

in one possible case, the second diffraction grating is a grating pitch adjustable diffraction grating. For example, the grating pitch of the second diffraction grating is mechanically adjustable.

In this case, the first electrical control signal sent by the control device to the second diffraction grating may be a control instruction instructing the second diffraction grating to adjust the grating physical spacing of the first sub-grating region until the second diffraction grating is in the light-shielding state.

In yet another possible implementation, the second diffraction grating is a diffraction grating with controllable diffraction coefficient. Accordingly, in the above embodiment, the first electrical control signal may be used to control the diffraction coefficient of at least one first sub-grating region in the second diffraction grating to be the diffraction coefficient corresponding to the opaque state.

For example, the second diffraction grating is an electrically controllable diffraction grating, and the diffraction parameters of the respective diffraction regions can be adjusted by adjusting the driving voltages applied to the different diffraction regions of the second diffraction grating. On the basis, the first electric control signal is used for controlling a target driving voltage applied to at least one first sub-grating region in the second diffraction grating, and the target driving voltage is applied to the first sub-grating region, so that the diffraction coefficient of the first sub-grating region is the diffraction coefficient corresponding to the opaque state.

Of course, an implementation manner of adjusting the diffraction coefficient by using an electrically controllable diffraction grating is described as an example, and in practical applications, other possibilities of adjusting the diffraction coefficient by using the electrically controllable diffraction grating may also be available, which is not limited to this.

Of course, the first diffraction grating may also be a controllable diffraction grating, and the first diffraction grating may also be a diffraction grating with a controllable diffraction coefficient, or a diffraction grating with an adjustable grating pitch.

It can be understood that, because the first display surface can be any one display surface of the transparent holographic display screen, the image projection system can project a virtual scene image on any one surface of the transparent holographic display screen, and the virtual scene image cannot be seen on the other display surface of the transparent holographic display screen, so that users on different display surfaces of the transparent holographic display screen can see different virtual scene images, and privacy of the virtual scene image presented on any one display surface of the transparent holographic display screen can be protected.

From the above, the image projection system of the present application includes a transparent holographic display screen, and diffraction gratings are superimposed on both sides of the transparent holographic display screen. On the basis, the control equipment can control at least one first projection light source in the plurality of projection light sources to project the virtual scene image to the first display surface of the transparent holographic display screen, and meanwhile, the control equipment can output an electric control signal to the diffraction grating superposed on the second display surface of the transparent holographic display screen. Because the electric control signal can control at least one sub-grating region in the light projection region of the at least one first projection light source in the diffraction grating on the second display surface to be in a light-tight state, when one surface of the transparent holographic display screen presents a virtual scene image, a user on the other surface of the transparent holographic display screen cannot see the virtual scene image, so that two surfaces of the transparent holographic display screen can present different virtual scene images, and the diversity and flexibility of presenting the virtual scene images are improved.

For ease of understanding, the benefits of the present embodiment are described below with reference to an application scenario, and in one possible implementation, the image projection system of the present application may be applied to a teaching scenario. In a teaching scene, the transparent holographic display screen can replace a blackboard or a whiteboard in a traditional classroom. Such as the application scenario diagram shown in fig. 2.

In the scenario shown in fig. 2, a teacher 202 and a student 203 are respectively located on two sides of the transparent holographic display screen 201 corresponding to the two display surfaces. For ease of understanding, the side of the teacher 202 opposite the transparent holographic display is referred to as the first display side of the transparent holographic display, and correspondingly, a plurality of students 203 are located on the other display side of the transparent holographic display.

Because the transparent holographic display screen is transparent, teacher 202 can not only see the virtual scene image presented by the first display surface of transparent holographic display screen 201, but also see through the transparent holographic display screen the students 203 in the real scene located at one side of the second display surface of the transparent holographic display screen.

In this scenario, if it is desired that the content entered by the teacher on the first display surface of the transparent holographic display screen be visible only on the first display surface and not visible to the student, the control device may determine a first virtual scene image to be presented to the first display surface based on the input content entered by the teacher on the first display surface.

On this basis, the control device may control at least one first projection light source capable of projecting a virtual image to the first display surface to project a first virtual scene image to the first display surface. Meanwhile, the control equipment determines a sub-diffraction grating area in the corresponding projection light path coverage area in the second diffraction grating superposed on the second display surface according to the projection light path of at least one projection light source, and the input content of the teacher can be invisible on the second display surface by adjusting the sub-diffraction grating area of the second diffraction grating to be in an opaque state, so that the student can not see the input content input and presented by the teacher on the first display surface.

For example, in fig. 2, for each student, the teacher writes the score of the student in the holographic transparent display screen at the corresponding position of the student, and the scores of the students are only visible to the teacher but not to the student.

It is to be understood that, here, the first virtual scene image presented on the first display surface is taken as an example of the input content input into the first display surface by the teacher, and in practical applications, the first virtual scene image may also be a virtual scene image preset by the teacher or selected and output currently, which is not limited to this. For example, in fig. 2, the teacher may also see some operation options on the first display surface that are only available for selection by the teacher, such as icons that compliment or trigger the output of applause to students for a certain student, and these contents may also be presented only on the first display surface but not on the second display surface side.

It can be understood that, in practical applications, in order to achieve privacy of viewing virtual scene images among multiple users located on the same side of the transparent holographic display screen, different virtual scene images need to be presented to different users on the same side of the transparent holographic display screen, so that the virtual scene images that can be viewed by users on different positions on the same side of the transparent holographic display screen are different.

To achieve this, the image projection system of the present application may further include an eye tracker. Fig. 3 is a schematic diagram of another embodiment of the image projection system of the present application.

In fig. 3, the image projection system comprises at least one eye tracker 304 in addition to the control device 301 of fig. 1, a transparent holographic display screen 302, a projection light source 303, a first diffraction grating superimposed on a first display surface of the transparent holographic display screen and a second diffraction grating (diffraction grating not shown) superimposed on a second display surface of the transparent holographic display screen.

The connection relationship and functions between the control device, the transparent holographic display screen, the projection light source, and the first diffraction grating and the second diffraction grating can be referred to in the related description of the previous embodiments.

In the embodiment of the present application, the eye tracker 304 is connected to the control device 301.

The eye tracker is capable of collecting eye positioning data of a user, which is used to locate the position of the eyes of the user.

The eye tracker may be disposed in a physical environment in which the transparent holographic display screen is located.

In this case, the control device may control at least one second projection light source of the plurality of projection light sources to project a second virtual scene image to the second display surface of the holographic transparent display screen, and send a second electrical control signal to the second diffraction grating.

The second electrical control signal is used for controlling a diffraction parameter of at least one second grating sub-region in the second diffraction grating, which is located on a light propagation path from the at least one second projection light source to a human eye position of a target user, so that a second virtual scene image projected by the at least one second projection light source is only projected to the human eye of the target user through the at least one second grating sub-region.

The target user is a user located on one side of the second display surface of the transparent holographic display screen. And when a plurality of users exist on one side of the second display surface, at least one second projection light source for projecting the second virtual scene image to the second display surface is different for different target users.

For different target users, the second virtual scene images projected to the positions of the eyes of the target users through the second display surface may also be different, and in general, the second virtual scene images corresponding to a plurality of target users are not completely the same and may be specifically set as required.

The second projection light source belongs to at least one projection light source which can project a virtual image to the second display surface of the holographic transparent display screen. For example, the second projection light source belongs to a projection light source which is arranged outside the holographic transparent display screen and faces the second display surface of the holographic transparent display screen.

For the sake of convenience of distinction, the virtual scene image that needs to be projected toward the second display surface is referred to as a second virtual scene image.

Meanwhile, since the second virtual scene image needs to be projected to the eye position of the target user through the second display surface and the second diffraction grating by the second projection light source, the second virtual scene image only needs to be displayed to the target user located in the second display surface side of the transparent holographic display screen and is invisible to other users located in the second display surface side except the target user.

In order to enable the second projection light source to project the second virtual scene image to the eye position of the target user through the second display surface and the second diffraction grating, the information such as diffraction parameters and the like required to be met by the second sub-grating region when the at least one second projection light source is projected to the eye position of the target user through the at least one second sub-grating region in the second diffraction grating can be determined by combining the projection light path from the at least one second projection light source to the eye position of the target user. Accordingly, a second electrical modulation signal may be sent to the second diffraction grating such that the second sub-grating region is at the corresponding diffraction parameter.

It will be appreciated that in the image projection system of fig. 3, there are many possibilities for the eye tracker.

In one possible case, the eye tracker may be an image collector. On this basis, user's image can be gathered through image collector, can include user's people's eye image in the user's image, on this basis, can regard user's image as the eye location data that analysis and location user's people's eye position.

On the basis, the control device can determine the eye position of the user according to the user image of the user collected by one or more eye trackers. For example, a human face image area is determined according to the user image, the human eye position in the human face image area is positioned, and the human eye position of the user is comprehensively calculated by combining the position of a human eye tracker and the like. It is understood that, in the case that the user image of the user is known, there are many possible specific implementations of calculating the position of the eyes of the user, which is not limited by the present application.

In yet another possible case, the eye tracker may further be a sensor such as an infrared detector capable of sensing the position of the user, and on this basis, the eye tracker may sense the position of the user and other related auxiliary information for locating the position of the eyes of the user.

Correspondingly, the control device can calculate the eye position of the user by combining the auxiliary information which is sensed by the eye tracker and used for positioning the eye position of the user, and the specific calculation mode is not limited.

From the foregoing, it will be appreciated that the second diffraction grating may take many possible forms. For example, in one possible case, the second diffraction grating may be a grating pitch adjustable diffraction grating. In this case, the second electrical control signal sent by the control device may be a control signal for adjusting the physical spacing of the gratings, and the control signal may include the second sub-grating. Correspondingly, the second diffraction grating adjusts the grating pitch of the second sub-grating region based on the second electric control signal, so that the second sub-grating region has diffraction parameters required for projecting the second virtual scene image to the human eyes of the target user.

In yet another possible implementation, the second diffraction grating is a diffraction grating with controllable diffraction coefficient. Correspondingly, the second electric control signal is used for controlling the diffraction coefficient of at least one second grating sub-area in the second diffraction grating to be the target diffraction coefficient. At least one second diffraction subregion of the second diffraction grating has a target diffraction coefficient such that the at least one second diffraction subregion is capable of projecting a second virtual scene image to the human eye of the target user.

It can be understood that, in the image projection system shown in fig. 3, the control device may determine, through the image capture device and the like, a user located on one side of the second display surface of the transparent holographic display screen, and meanwhile, the control device may take each user on one side of the second display surface as a target user, and project different second virtual scene images to different target users through the second display surface and the second diffraction grating according to actual needs.

In an alternative, in order to enable a more targeted projection of the virtual scene image to the users on the second display surface side, it is also possible for a first user on the first display surface side of the transparent holographic display to select one user from the users on the second display surface side as the target user.

For the sake of convenience of distinction, a user on the first display surface side of the transparent holographic display screen is referred to as a first user, and a user on the second display surface side of the transparent holographic display screen is referred to as a second user.

Specifically, the image projection system shown in fig. 3 may further include: at least one interaction sensor (not shown in fig. 3).

The interaction sensor collects input operation data input to the first display surface by a first user and transmits the input operation data to the control equipment.

In one possible case, the interaction sensor may be arranged outside the transparent holographic display screen and connected to the control device. For example, the interaction sensor may be an image collector, and the image collector may collect input operation data input to the first display surface by a first user on one side of the first display surface. Of course, the interaction sensor may also be a sensor used in mixed reality or augmented reality technology, which is capable of positioning the action behavior of the user's limb, and this is not limited.

In yet another possible case, the interaction sensor may be a touch sensing unit disposed on the transparent holographic display screen. In this case, the interaction sensor is connected to the control device via a transparent holographic display.

Multiple types of interaction sensors may also be provided simultaneously in the image projection system to more fully and accurately determine the input data entered by the user.

Correspondingly, the control device is also used for determining a target user selected by the first user according to the input operation data input by the first user, wherein the target user belongs to at least one second user positioned on one side of the second display surface of the display screen.

For ease of understanding, the following description is made in connection with yet another application scenario.

As shown in fig. 4, which shows a schematic diagram of yet another application scenario to which the scheme of the present application is applicable. For convenience of description, the application scenario is still taken as an example of a teaching scenario. As can be seen from fig. 4, a teacher 402 is present on the first display side of the transparent holographic display 401. The teacher can see through the transparent holographic display 401 the students 403 in different seats in the classroom, which are located on the second display side of the transparent holographic display.

On this basis, if a teacher wishes to output a particular virtual scene image to a student in a classroom, the teacher clicks the student at the location where the student is seen on the transparent holographic display, as in fig. 4, the teacher 402 clicks the leftmost second row of target students 404, which are the target users selected by the teacher 402.

Correspondingly, the control device can obtain images in the classroom collected by at least one image collection device (generally a plurality of image collection devices) arranged in the classroom, and determines a target student pointed by the input operation input by the teacher to the first display surface of the transparent holographic display screen by combining the images in the classroom.

Alternatively, the control device determines an input position point of the selection operation input by the teacher based on the touch sensing unit on the transparent holographic display screen, and then determines a target student to which the input position point points, in combination with the relative position of each student with respect to the transparent holographic display screen (which may be preset or determined by a student image collected by the image collecting device, etc.).

On the basis of the above, the control device may determine that a second virtual scene image needs to be projected to the target student. For example, after determining the target student selected by the teacher, the control device may take the content input by the teacher at the target student position in the first display surface as the second virtual scene image to be presented to the target student; or after the control device determines the target student selected by the teacher, the control device may display an operation option, such as an icon of a clapper or a smiling face shown in fig. 2, at a position corresponding to the target student in the first display surface of the transparent holographic display screen, and on this basis, may determine the virtual scene image of the clapper or the smiling face, which is triggered and displayed by the operation icon selected by the teacher, as the second virtual scene image that needs to be displayed to the target student.

Further, the control device determines at least one second projection light source required for projecting a second virtual scene image to the target student based on the position of human eyes of the target student, and controls the second projection light source to project the second virtual scene image to the second display surface. Meanwhile, the control device determines diffraction parameters required by a sub-grating area on the second diffraction grating in the projection optical path according to the projection optical path from the at least one second projection light source to the eye position of the target student, and controls the sub-grating area to have corresponding diffraction parameters, so that the sub-grating area can diffract a second virtual scene image projected by the second projection light source to the eye position of the target student, and a teacher hopes that the second virtual scene image of the target student can only be seen by the target student and cannot be seen by other students.

On the other hand, the present application also provides an image projection method applied to the control device in the image projection system as in any one of the above embodiments.

As shown in fig. 5, which shows a schematic flowchart of an embodiment of an image projection method according to the present application, the method of the present embodiment is applied to a control device in an image projection system in any of the foregoing embodiments. The method of the embodiment may include:

s501, determining a first virtual scene image to be projected to a first display surface of a transparent holographic display screen.

The first display surface of the transparent holographic display screen is overlaid with the first diffraction grating, and the second display surface is overlaid with the second diffraction grating, which is specifically referred to the foregoing description, and is not repeated herein.

For example, after an input operation input by a first user on the first display surface is detected, the first virtual scene image to be projected is determined based on the input operation.

For another example, the first virtual scene image may be determined according to a virtual scene image played by the first display surface before the current time.

Of course, there may be other ways of determining the first virtual scene image, which is not limited in this respect.

S502, at least one first projection light source in the plurality of projection light sources is controlled to project a first virtual scene image to the first display surface.

For example, at least one first projection light source capable of projecting the virtual scene image to the first display surface may be determined from the plurality of projection light sources, and then the at least one first projection light source may be controlled to project the first virtual scene image outward.

And S503, outputting a first electric control signal to the second diffraction grating.

The first electrical control signal is used for controlling at least one first sub-grating region in the second diffraction grating, which is located in the light projection region of at least one first projection light source, to be in an opaque state, so that the first sub-grating region shields a first virtual scene image projected by at least one first projection light source, and the first virtual scene image is invisible on the second display surface.

In addition, the sequence of steps S502 and S503 is not limited to that shown in fig. 5, and in practical applications, in order to minimize the situation that the first virtual scene image is visible on the second display surface, step S503 may be executed before step S502 or may be executed in synchronization with step S502.

The relevant steps in this embodiment are the same as the operations executed by the control device in the image projection system, and specific reference may be made to the relevant descriptions of the previous embodiments, which are not described herein again.

Based on the introduction of the foregoing system embodiment, it can be seen that the application also implements the function of projecting different second virtual scene images to different second users on one side of the second display surface of the holographic transparent display, so that the virtual scene images that can be seen by the second users at different positions on one side of the second display surface may be different, and the content that the second users see at the positions of the second users is not seen by other second users, that is, privacy protection of the content that each second user views is implemented.

To achieve the object, the control device may further determine a target user located on a side of the second display surface of the display screen; controlling at least one second projection light source in the plurality of projection light sources to project a second virtual scene image to the second display surface; and sending a second electrical control signal to the second diffraction grating. The second electrical control signal is used for controlling a diffraction parameter of at least one second grating sub-area in the second diffraction grating, which is located on a light propagation path from the at least one second projection light source to a human eye position of a target user, so that a second virtual scene image projected by the at least one second projection light source is only projected to the human eye of the target user through the at least one second grating sub-area.

One implementation manner of determining the target user may be: obtaining input operation input by a first user on a first display surface, wherein the first user is a user positioned on one side of the first display surface of the transparent holographic display screen; and determining a target user for the input operation based on the input position of the input operation on the first display surface and the position of at least one second user positioned at one side of the second display surface. If the input position points to the position of a certain second user, the second user is the target user.

It can be understood that, in order to enable the second user to see the 3-dimensional virtual scene image and reduce the phenomenon that the two second users see the same virtual scene image at different positions due to the close positions of the two second users, the present application may further respectively project different virtual scene images for the left eye and the right eye of the second user, so that the second user sees a three-dimensional virtual scene image synthesized by the two virtual scene images projected to the left eye and the right eye according to the binocular disparity of the second user.

In the following, description is made in conjunction with an implementation manner, as shown in fig. 6, which illustrates a flowchart of projecting a second virtual scene image to a target user in the image projection method provided in the present application, and the method of this embodiment is applied to the control device in the image projection system in any of the foregoing embodiments. The method of the embodiment may include:

s601, obtaining the input operation input by the first user on the first display surface.

The first user is a user located on one side of the first display surface of the transparent holographic display screen.

S602, determining a target user for the input operation based on the input position of the input operation on the first display surface and the position of at least one second user positioned on one side of the second display surface.

The target user belongs to the at least one second user.

The above steps S601 to S602 are one implementation of determining the target user, but it is understood that the other manners mentioned above are also applicable to the present embodiment.

S603, the left eye position and the right eye position of the target user are obtained.

The positions of the left eye and the right eye of the target user can be determined in the same way as the specific way of determining the positions of the eyes of the target user. For example, the left eye position and the right eye position of the target user may be analyzed based on the user image of the target user captured by the image capturing device. Of course, the left eye position and the right eye position of the target user may also be determined by the positioning data of the target user sensed by the infrared sensor, which is not limited herein.

S604, determining a second virtual scene image to be presented to the target user.

For example, the second virtual scene image may be determined based on an input operation or a selection operation of the first user located on the first display surface side of the transparent holographic display screen.

Of course, the present application is not limited to what manner to determine the second virtual scene image that needs to be presented to the target user, and other manners are also applicable to this embodiment.

S605, based on the second virtual scene image, determine a first sub virtual scene image to be projected to the left eye of the target user and a second sub virtual scene image to be projected to the right eye of the target user.

The first sub virtual scene image and the second sub virtual scene image are virtual images for generating a three-dimensional second virtual scene image in an overlapping mode.

For example, the first sub virtual scene image and the second sub virtual scene image may be obtained based on the stored corresponding sub virtual scene image of the second virtual scene image.

S606, determining at least one third projection light source required for projecting the first sub virtual scene image to the left eye of the target user based on the left eye position of the target user.

S607, determining at least one fourth projection light source required for projecting the second sub virtual scene image to the right eye of the target user based on the right eye position of the target user.

Wherein the third projection light source and the fourth projection light source actually belong to at least one second projection light source corresponding to the target user.

Wherein the at least one third projection light source belongs to a part or all of projection light sources capable of light projection to the left eye of the target user via the second display surface; and at least one fourth projection light source belongs to a part or all of projection light sources capable of projecting light to the right eye of the target user via the second display surface.

S608, controlling the at least one third projection light source to project a first sub virtual scene image onto the second display surface, and controlling the at least one fourth projection light source to project a second sub virtual scene image onto the second display surface, so as to present the second virtual scene image superimposed by the first sub virtual scene image and the second sub virtual scene image to the target user.

And S609, sending a first electronic regulation electronic signal to the second diffraction grating.

The first electrical control sub-signal is used for controlling at least one third grating sub-area in the second diffraction grating, which is located on a light propagation path from the at least one third projection light source to the left eye position of the target user, to have a first diffraction parameter, so that the first sub-virtual scene image projected by the at least one third projection light source is projected to only the left eye of the target user through the at least one third grating sub-area.

And under the condition that the third grating sub-area has the first diffraction parameter, after the first sub-virtual scene image projected by the at least one third projection light source reaches the third grating sub-area through the second display surface, the first sub-virtual scene image can be projected to the position of the left eye of the target user through the grating diffraction of the third grating sub-area.

S610, sending a second electrical modulator signal to the second diffraction grating.

The second electrical control sub-signal is used for controlling at least one fourth grating sub-area in the second diffraction grating, which is located on a light propagation path from the at least one fourth projection light source to the right eye position of the target user, to have a second diffraction parameter, so that a second sub-virtual scene image projected by the at least one fourth projection light source is projected to only the right eye of the target user through the at least one fourth grating sub-area.

Similarly, in the case that the fourth sub-grating region has the second diffraction parameter, after the first sub-virtual scene image projected by the at least one fourth projection light source reaches the fourth grating sub-region via the second display surface, the second sub-virtual scene image can be projected to the right eye position of the target user through the grating diffraction of the fourth grating sub-region.

As can be seen from the above, since the first sub virtual scene image can be projected only into the left eye of the target user and the second sub virtual scene image can be projected only into the right eye of the target user, the target user can see the three-dimensional second virtual scene image synthesized from the first sub virtual scene image and the second sub virtual scene image based on the binocular disparity. Moreover, due to the control of the control device on the diffraction parameters of the control light source and the second diffraction grating, only the left eye of the target user can see the first sub-virtual scene image, and only the right eye of the target user can see the second sub-virtual scene image, so that only the target user can see the synthesized second virtual scene image, and other users on one side of the second display surface of the transparent holographic display screen cannot see the second virtual scene image, thereby improving the privacy protection of the virtual scene image.

It can be understood that, in the present application, it can also be implemented that, for a position of a certain first user on the first display surface side of the transparent holographic display screen, projection of the first virtual scene image is reasonably controlled, so that the first virtual scene image can be seen only at the position of the first user, and the first virtual scene image cannot be seen at positions of other first users on the first display surface side.

For example, referring to fig. 7, which shows another schematic flow chart of an image projection method of the present application, the method of the present embodiment is applied to a control device, and the present embodiment may include:

s701, determining a first virtual scene image to be projected to a first display surface of the transparent holographic display screen.

S702, determining the positions of the human eyes of a first user on one side of a first display surface of a display screen.

The way of positioning the eye position of the first user is the same as the specific way of positioning the eye position of the target user, and is not described herein again.

S703, determining at least one first projection light source required to project a first virtual scene image to the first user from the plurality of projection light sources.

For example, at least one first projection light source capable of projecting a light source to a position toward the eyes of the first user is determined according to the light projection angle of each projection light source and the positions of the eyes of the first user.

S704, at least one fifth grating sub-area of the first diffraction grating is determined in the light propagation path of the at least one first projection light source to the eye position of the first user.

The fifth grating sub-region is a diffraction grating region in the first diffraction grating, which is located on a light propagation path from the first projection light source to a position of human eyes of the first user, and therefore, a light diffraction parameter of the fifth grating sub-region needs to be reasonably adjusted, so that the fifth grating sub-region can diffract light projected by the first projection light source to the human eyes of the first user.

S705, sending a third electrical control signal to the first diffraction grating.

The third electrical control signal is used for controlling the diffraction parameter of the at least one fifth grating subregion, so that the first virtual scene image projected by the at least one first projection light source is diffracted to the position of the human eyes of the first user through the at least one fifth grating subregion.

For example, when the first diffraction grating is a diffraction grating with a physically adjustable grating pitch, the third electrical control signal is used to indicate the grating pitch in the fifth grating sub-region of the first diffraction grating, so that the diffraction parameter of the fifth grating sub-region can meet the projection requirement that the first virtual scene image projected by the first projection light source is diffracted to the eye position of the first user.

In another example, if the first diffraction grating is a diffraction grating with a controllable diffraction coefficient, the third electrical control signal is used to control the diffraction coefficient of the fifth grating sub-area to be the designated diffraction coefficient. And under the condition that the fifth grating subarea is positioned at the designated diffraction coefficient, the fifth grating subarea can diffract the first virtual scene image projected by the first projection light source to the eye position of the first user.

S706, controlling at least one first projection light source to project a first virtual scene image to the first display surface.

S707, the first electrical control signal is output to the second diffraction grating.

The first electrical control signal is used for controlling at least one first sub-grating region in the second diffraction grating, which is located in the light projection region of at least one first projection light source, to be in an opaque state, so that the first sub-grating region shields a first virtual scene image projected by at least one first projection light source, and the first virtual scene image is invisible on the second display surface.

In yet another aspect, the present application further provides an electronic device, as shown in fig. 8, which shows a schematic structural diagram of the electronic device, and the electronic device may be any type of electronic device, and the electronic device at least includes a memory 801 and a processor 802;

wherein the processor 801 is adapted to perform the image projection method as in any of the above embodiments.

The memory 802 is used to store programs needed for the processor to perform operations.

It is to be understood that the electronic device may further include a display unit 803 and an input unit 804.

Of course, the electronic device may have more or less components than those shown in fig. 8, which is not limited thereto.

In another aspect, the present application further provides a computer-readable storage medium having at least one instruction, at least one program, a set of codes, or a set of instructions stored therein, which is loaded and executed by a processor to implement the image projection method according to any one of the above embodiments.

The present application also proposes a computer program comprising computer instructions stored in a computer readable storage medium. A computer program for performing the image projection method as in any one of the above embodiments, when run on an electronic device.

It should be noted that, in the present specification, the embodiments are all described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments may be referred to each other. Meanwhile, the features described in the embodiments of the present specification may be replaced or combined with each other, so that those skilled in the art can implement or use the present application. For the device-like embodiment, since it is basically similar to the method embodiment, the description is simple, and for the relevant points, reference may be made to the partial description of the method embodiment.

Finally, it should also be noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

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