CN212541009U - Transmission type geometric holographic display system for optimizing display configuration - Google Patents

Abstract

The utility model relates to the field of 3D display, and discloses a transmission type geometric holographic display system for optimizing display configuration, which comprises at least one projector; the transmission type geometric holographic screen is used for optically converting the picture on one side to the other side to form an optical conjugate image; a support structure providing support for the projector and the transmissive geometric holographic screen; and a controller electrically connected to the projector; the display system comprises a plurality of viewpoints, the effective projection area of the transmission type geometric holographic screen is SP square meter and single viewpointThe area is an SL square meter, the optical path distance between the center of the outermost lens of any single projector and the center of the transmission type geometric holographic screen in a working state is L meters, and the effective ornamental solid angle of each viewpoint meets the following requirements:

by carrying out global optimization constraint on all components of the whole system, the display system can be always in an optimal configuration interval, the cost is controlled, and meanwhile, the comprehensive performance of the display system can be optimized.

Description

Transmission type geometric holographic display system for optimizing display configuration

Technical Field

The utility model belongs to the technical field of 3D shows and specifically relates to a transmissive geometric holography display system who optimizes display configuration is related to.

Background

In recent years, 3D display technology is very popular, and more research institutes are beginning to invest in the development of 3D display technology. But so far there are few holographic display schemes that can really approach those in science fiction movies. Most of them use stereo image pair schemes with very low technical threshold to realize pseudo 3D display, and their viewing experience is not ideal.

The transmission geometry holographic display system patent publication CN111338175A proposes a new holographic display scheme. The scheme can realize real 3D image reproduction in display principle, can enable a user to watch a display picture in a real physical world mode, and is a very ideal 3D display scheme. But currently in the early stages of technology development, technology accumulation is relatively small. Therefore, although it is ideal in display principle, it is difficult to fully maximize the advantages of the display in practical applications due to the limitations of the knowledge of designers. The brand new display mode is greatly different from the prior flat panel display such as LCD, glasses display equipment and the like in display principle and display mode, so the design skill/rule of the traditional display system can not be used for reference on the new display system at all. The novel display system relates to the mutual matching of a plurality of display components, in particular to the mutual matching between a projector (such as a holographic projector) and a geometric holographic screen and a window following movement mechanism. In practical applications, how to select the aperture of the projector, how to set the corresponding geometric holographic screen, how to reserve a tracking motion space in the tracking process, and the like are very difficult to determine. If the matching relationship among the components of the system is not well treated, over-design of one component and under-design of another component are caused, so that the cost of the system is high but the display effect is not ideal. Because the structure of the projector (especially the holographic projector) is too complicated compared with the common projector, the cost is very high, and the geometric holographic screen also needs to be produced by micron-sized processing technology to produce screens with decimeter or even meter-sized dimensions, and the cost is high, so that no matter which component is over-designed, a large amount of cost waste can be caused, and similar to the barrel principle, the performance potential of the system is limited by the short plate component, and therefore, the optimal performance cannot be exerted. In addition, if the design is not reasonable, the window following movement is also easy to cause the loss of the heel, which greatly affects the user experience.

In summary, a common designer of such a system is difficult to grasp at the time of design, and although the system can be built in principle, the relationship between the characteristic parameters is often not good. When a designer designs the image, he or she may seek a large window in one way, so that the aberration of the system is very large, the image quality is limited, sometimes a large geometric holographic screen is used for seeking a large field of view, but the projector cannot be matched to cause field of view waste or cannot be matched with an application scene to reasonably utilize the high resolution of the imaging element. The prototype made in this way often cannot enable the display system to exert the optimal display performance, but can enlarge some inevitable inherent defects, so that the user experience is very poor.

SUMMERY OF THE UTILITY MODEL

In order to solve or partially solve the defects of the prior art, the display configuration is optimized, the display system can be always in the optimal configuration interval by carrying out global optimization constraint on all the components of the whole system, the cost is controlled, and the comprehensive performance of the display system can be optimized.

A transmissive geometry holographic display system for optimizing display configuration, comprising:

at least one projector for projecting picture information in space;

the position of the transmission type geometric holographic screen corresponds to that of the projector, and the transmission type geometric holographic screen is used for optically converting the picture on one side to the other side to form an optical conjugate image;

further to the projector, and further to the transmissive geometric holographic screen, a support structure providing physical structural support; and

the transmission type geometric holography display system comprises a plurality of viewpoints, the effective projection area of the transmission type geometric holography screen is SP square meter, the area of a single viewpoint is SL square meter, the optical path distance between the center of the outermost lens and the center of the transmission type geometric holography screen is L meters, and the effective ornamental solid angle of each viewpoint meets the following requirements:

further, the maximum value L of the optical path distance L between the center of the outermost lens and the center of the transmission type geometric holographic screen is further_MAXAnd a minimum value L_MINThe ratio of (A) to (B) satisfies:

furthermore, the effective projection area SP of the transmission type geometric holographic screen ranges from 0.005 to 1.5 square meters.

Further, the range of the single viewpoint area SL is 0.000004-0.5 square meters.

Further, the optical path distance L between the center of the outermost lens and the center of the transmission type geometric holographic screen of the single projector ranges from 0.1 meter to 10 meters.

The optical path folding mirror group further comprises a plane mirror with a reflection function, and the plane mirror is used for changing the propagation path of the projection light.

Further, the optical path folding mirror group is further connected with the supporting structure.

Further, the support structure is further a structure that can be deformed and/or moved, and is further electrically connected to the controller.

The system further comprises an interactive action capturing unit electrically connected with the controller, the interactive action capturing unit is further used for recognizing the interactive action of the user and sending the interactive action information of the user to the controller, and the controller is further used for adjusting the content of the display picture according to the received interactive action information of the user.

The human eye tracking unit is further used for tracking the position of human eyes and sending the positioning information of the human eyes to the controller, and the controller is further used for controlling the supporting structure according to the received human eye positioning information acquired by the human eye tracking unit and making corresponding action response to adjust the spatial position of each part of the display system so that the eyes of a user are always in the visual space of the system.

Compared with the prior art, the utility model has the advantages of:

1. the projector, the transmission type geometric holographic screen and the supporting structure are subjected to global optimization setting, so that the display system can be always in an optimal configuration interval, the cost is controlled, and the comprehensive performance of the display system can be optimized;

2. the reasonable effective viewing solid angle can avoid the poor 3D performance caused by the small effective viewing solid angle and the situation that the aberration generated by pursuing the large solid angle is too large to realize the maximum system display capability.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Figure 1 is a schematic diagram of the system of the invention comprising a projector 1,

figure 2 is a schematic diagram of the system of the present invention comprising 2 projectors 1,

FIG. 3 is a schematic diagram of the system of the present invention, which is based on FIG. 1 and adds an optical folding lens set 5 on the same side of the projector 1,

FIG. 4 is a schematic diagram of the system of the present invention and the optical path of the transmission type geometric holographic screen 2 with an additional optical path folding lens set 5 on the other side based on FIG. 3,

fig. 5 is a schematic diagram of a system based on fig. 1, with the addition of an interactive motion capture unit 6 and a human eye tracking unit 7,

FIG. 6 is a schematic diagram showing an effective projected area SP of the transmissive geometric hologram 2, an area SL of a light-transmitting portion of an outermost lens of the projector 1, and an optical path length L between a center of the outermost lens of the projector 1 and a center of the transmissive geometric hologram 2,

fig. 7 is a schematic diagram of the optical path length L of the display system including the optical path folding lens group 5, where the reference numbers are as follows:

the device comprises a projector 1, a transmission type geometric holographic screen 2, a supporting structure 3, a controller 4, an optical path folding mirror group 5, an interactive action capturing unit 6 and a human eye tracking unit 7.

Detailed Description

In order to make the technical solution of the present invention better understood, the present invention is described in detail below with reference to the accompanying drawings, and the description of the present invention is only exemplary and explanatory, and should not be construed as limiting the scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

It should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like refer to the orientation or positional relationship shown in the drawings, or the orientation or positional relationship that the utility model is usually placed when in use, and are used for convenience of description and simplification of description, but do not refer to or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 to 7, the present invention provides a transmission type geometric holographic display system with optimized display configuration, which comprises at least one projector 1, a transmission type geometric holographic screen 2, a supporting structure 3 and a controller 4;

the projector 1 is used for projecting picture information (picture information with depth) in space, the utility model discloses can directly adopt holographic projector as projector 1, realize 3D and show;

the method can also adopt a common projection device capable of projecting a two-dimensional picture to realize that the two-dimensional picture is projected on a certain focal plane in a space, then the depth of field and picture content of the two-dimensional picture are adjusted through the controller 4 (the picture content is presented, and simultaneously, the real distance feeling between the picture and a user can be presented, which is obviously different from a common projection display system that the common projection display system can only display the picture on a fixed plane, so that the picture has no depth information expression effect), the process of focal depth adjustment in the actual working process can be real-time, or the focal depth adjustment can be performed once at intervals according to the picture display content (the whole depth of field of the picture is maintained at a level in a period of video or other videos usually, and the picture has larger jitter of the depth of field only when the scene is switched);

for example, a common projection device may be further optically designed to realize 3D display on the basis of a single projector, and reference may be made to an all-solid-state holographic projector with application number 202010029144.5, and a technical scheme of realizing three-dimensional picture display by adding some optical elements inside the projector for optical design is not specifically limited herein;

the transmission type geometric holographic screen 2 is a screen which converges an image point positioned on one side to the other side to form a conjugate image point, the position of the screen corresponds to the projector 1, and the screen is used for converting an image projected by the projector 1 to an optical conjugate position relative to the transmission type geometric holographic screen 2, and the screen has the function of converging a divergent picture projected by the projector 1 to a window position for a user to watch after conversion;

when the 2D picture needs to be compatibly displayed, the transmission type geometric holographic screen 2 can be replaced by a common projection screen, such as a common rear projection screen;

the support structure 3 is respectively matched with the projector 1 and the transmission type geometric holographic screen 2 to provide physical structural support for the projector and the transmission type geometric holographic screen, specifically, the support structure 3 can be made into a support frame with a fixed structure, at the moment, the whole display system of the utility model is fixed, and a user can observe a picture only in a fixed direction;

the controller 4 is electrically connected with the projector 1, and the projector 1 can adjust the depth of field and the picture content of the projected picture according to the control signal of the controller 4;

in order to increase the flexibility of the display system, the support structure 3 is set to be a movable and/or deformable structure, the support structure 3 and the controller 4 are electrically connected, the support structure 3 makes corresponding response actions according to the control information of the controller 4, so as to realize the relative movement and/or the overall movement between the projector 1 and the transmissive geometric holographic screen 2, so that the visual window of the system always covers the eyes of the user, so that the user can normally view the picture in different orientations, it should be noted that the support structure 3 is a general prior art, and those skilled in the art can design themselves according to the spatial conditions of the practical application, for example: by using some hinge structures and structures similar to the umbrella shaft or the umbrella ribs, the skilled person can easily design structures meeting the requirements, which are not limited in detail herein;

as shown in fig. 5, as a preferred solution, the holographic display system of the present invention further includes an interactive action capturing unit 6 electrically connected to the controller 4, the interactive action capturing unit 6 is configured to recognize the interactive action of the user and send the interactive action information of the user to the controller 4, the controller 4 adjusts the content of the display screen according to the received interactive action information of the user obtained by the interactive action capturing unit 6, so as to realize the interactive action between the user and the screen, specifically, a camera is used to identify the gesture action of the user in combination with a machine vision technology to obtain the interactive information of the user, so as to control the movement and/or deformation of the supporting structure 3, thereby adjusting the spatial position and posture of each component of the system, the controller 4 can also adjust the content of the display screen in real time according to the received interactive action information of the user obtained by the interactive action capturing unit 6, the method includes the steps that interaction between a user and a picture is achieved, for example, the picture is controlled to translate according to a translation gesture signal, or operations such as amplification, zooming-in, zooming-out and touch of the picture are controlled according to other corresponding interaction;

the arrangement of the interactive motion capture unit 6 has positive significance for application scenarios like wearable applications where the spatial position of the user relative to the display system is fixed;

in addition, for an application scene that a user changes in real time relative to the spatial position of the display system, a human eye tracking unit 7 electrically connected with the controller 4 needs to be arranged, the human eye tracking unit 7 is used for tracking the position of human eyes and sending the positioning information of the human eyes to the controller 4, the controller 4 controls the support structure 3 to make corresponding action response according to the received human eye positioning information acquired by the human eye tracking unit 7, so as to adjust the spatial positions of the components (the projector 1, the transmission-type geometric holographic screen 2 and the optical path folding mirror group 5), and the eyes of the user are always in the visible space of the system, so that the user can always receive the projection information even in a moving state and normally watch a picture.

In practical applications, the human eye tracking unit 7 and the interactive motion capture unit 6 may be integrated in the same device, for example, a machine vision camera device or the like.

As shown in fig. 3 and 4, in order to further improve the flexibility of the system, a light path folding mirror group 5 may be further disposed on one side or both sides of the imaging optical system, the light path folding mirror group 5 is also connected to the support structure 3, and the light path folding mirror group 5 at least includes a reflecting mirror, so that the imaging optical path can be adjusted to adapt to various application space scenes. For the holographic display system comprising the optical path folding mirror group 5, the projector 1, the transmission type geometric holographic screen 2 and the optical path folding mirror group 5 can be simultaneously controlled to perform relative or integral motion through the supporting structure 3, so that real-time adjustment is realized, and the normal watching of a user is ensured.

The utility model discloses a display system is including a plurality of viewpoints, and arbitrary single viewpoint area is the SL square meter, and transmission type geometric sense holographically screened 2's effective projection area is the SP square meter, and single projector 1 outside lens center is L meter with optical path distance between transmission type geometric sense holographically screened 2's the center, and the effective angle of vwatching the solid of each viewpoint all satisfies:

for a related concept explanation of the viewpoint, see a transmission type geometric holographic display system with publication number CN 111338175A;

the preferable range of the effective projection area SP of the transmission-type geometric holographic screen 2 is 0.005-1.5 square meters, specifically, the area of the maximum shadow which can be formed by the transmission-type geometric holographic screen 2 under the irradiation of parallel light, and the effective projection area SP can also be directly placed on a plane and calculated according to the area of the covered plane. In actual design, a regular shape can be directly calculated by using a geometric relation, for example, a rectangular screen can be directly calculated by using the length and the width, and for a special-shaped screen, a curved screen and the like, the area calculation is difficult to be directly performed, and the special-shaped screen and the curved screen can be placed on a plane to be calculated according to the coverage area;

the preferred range of the single viewpoint area SL is 0.000004-0.5 square meter, the single viewpoint area should correspond to the area of the light transmission part of the outermost lens of the projector 1, and a description will be given by taking one viewpoint or a plurality of viewpoints provided by one projector 1 as an example:

as shown in fig. 6, when the projector 1 provides a viewpoint, the single viewpoint area SL is equal to the area of the light-transmitting portion of the outermost lens of the projector 1;

when the projector 1 provides two viewpoints, the single viewpoint area SL is equal to half of the area of the light-transmitting part of the outermost lens of the projector 1;

similarly, when N viewpoints are provided, the area SL of a single viewpoint is equal to 1/N of the area of the light-transmitting part of the outermost lens of the projector 1, and N is preferably 1-6;

the calculation method of the light transmission part area of the outermost lens of the projector 1 is the same as the calculation method of the effective projection area of the transmission type geometric holographic screen 2;

the optimal range of the optical path distance L between the center of the outermost lens of the single projector 1 and the center of the transmission type geometric holographic screen 2 is 0.1-10 m, and the maximum value L of the optical path distance L between the center of the outermost lens of the single projector 1 and the center of the transmission type geometric holographic screen 2 in the working state_MAXAnd a minimum value L_MINThe ratio of (A) should satisfy:

the tracking range can be matched with the user motion range better; further, in order to match the range of movement of the user in an indoor scene such as an office, it is more preferable

Can measure the distance between outermost mirror surface center and the 2 centers of transmission-type geometric hologram screen through the tape during design, to the display system who contains light path folding mirror group 5, can cover one deck light absorption membrane (like black paper) on light path folding mirror group 5 surfaces, set up a aperture on the membrane, only the position of aperture can reflect light like this, the unable reflected light of other positions. The action point of the light ray emitted from the center of the outermost lens of the projector 1 and finally irradiated on the center of the transmission-type geometric holographic screen 2 on each lens of the optical path folding mirror group 5 can be found by changing the position of the small hole by moving the light absorption film, so that the optical path distance in the process can be measured, of course, the optical path distance L can also be directly calculated according to the geometric relationship, and based on the above test method, for the display system comprising the optical path folding mirror group 5, L is the sum of L1 and L2 shown in fig. 7;

it should be noted that, because the display system needs to continuously adjust the position of the window according to the eye position of the user when working (when projecting and displaying a 3D picture to the user), L is not a fixed value but a range, and therefore, it needs to be ensured that any L value in the range meets the above formula when designing; it should be noted that L is a geometric relationship dimension during the over-working process, i.e. a characteristic of the system in a state of normally providing a display content for a user, and a value of L does not need to satisfy a formula limitation when the system is in a non-working state or a storage state.

Of course L may be set to a constant value for a wearable/stationary application.

The principles of the effective ornamental cube corner design rules are briefly described below: the holographic display system realizes screen display by a light field reconstruction means and can reproduce a stereoscopic image with depth information. However, merely presenting depth information is not sufficient to provide sufficient visual impact, and in many application scenarios, a certain effective viewing solid angle is required to enable a user to have a better usage experience. In order to pursue an extreme 3D visual experience to enable virtual display content to achieve real world-like optical effects, a solid angle of about 5.2 steradians needs to be provided. Generally, in a life scene, a comfortable 3D image can be represented by applying the method with a sphere degree of more than 0.7, and for some special scenes, such as a driving navigation scene or an XR scene, a virtual object and a real object are fused and displayed, when a user gazing area is concentrated, an effective watching solid angle of more than 0.0076 can meet the use requirement. In summary, the solid angle of the display of a single viewpoint needs to be set between 0.0076 and 5.2.

For the display system of the invention, the ideal configuration angle of the included angle between the connecting line (chief ray) between the center of the projection lens and the center of the transmission-type geometric holographic screen 2 and the transmission-type geometric holographic screen is 45 degrees, but the holographic display system can follow the movement of a user when working, so the ideal configuration angle can not be always kept, and the included angle is smaller under certain working conditions, so the immersion feeling under the conditions needs to be considered when designing. When the included angle between the main light ray and the transmission type geometric holographic screen 2 is 35 degrees, if certain immersion feeling can be guaranteed, the overall use experience feeling of the system is very good, and the conclusion is also confirmed through experiments and user experience feedback. Under the configuration, the effective light field control area of the transmission-type geometric holographic screen can be approximately SP · sin (35 degrees), the area SL occupied by the window is required to be deducted to be corrected in consideration of certain size of the window, and then a very accurate approximate value of the effective ornamental solid angle displayed by the actual display system can be calculated by dividing the distance between the window (which is also the center of the outermost mirror surface of the projector) and the center of the transmission-type geometric holographic screen 2.

The following description is given in conjunction with the examples, in particular in Table 1:

TABLE 1

The above embodiments show some more desirable configuration modes. Although all dimensions in the above embodiments are in meters (m), it is not limited to use these dimensions, and geometric similarity is considered in practical applications, all dimensions are scaled as a whole, or any other arbitrary combination of dimensions forms a solid angle similar to the embodiments, and the display effect will be consistent and will not change significantly. In fact, in the practical test, the whole scaling range of the numerical values in some embodiments is 0.001-1000 times and other different size combinations are also tested, as long as the effective viewing solid angle is similar, the user experience does not feel the difference between different sizes, further explaining that the implementation size is not a key factor influencing the effect, and the effective viewing solid angle is the actual viewing solid angle.

The practical application can be further preferably designed according to application scenes:

1) for desktop class application scenarios:

in an office scene, the requirement for effectively viewing the three-dimensional angle is low, preferably 0.2-0.6, a good three-dimensional effect can be shown, meanwhile, a certain immersion feeling is achieved, and the office requirements under most conditions can be met;

in a game entertainment scene, the optimal solid angle for effective appreciation is 0.6-0.8, a good three-dimensional effect can be shown at the moment, and the immersion feeling is further improved;

under application scenes such as design, research and development, simulation and the like, the optimal solid angle for effective appreciation is 0.8-1.2, at the moment, the three-dimensional effect and the immersion feeling are further improved, and the effect of linking with the physical world is achieved

2) For a wearable application scenario:

for the glasses type auxiliary display scene, the effective display effective viewing solid angle of each viewpoint is further preferably 1.2-2.2, and sufficient immersion is provided;

the effective viewing solid angle of each viewpoint of the head-wearing/wearing type video application scene is preferably 2.2-3.4, and the display solid angle is larger and the immersion is stronger;

the effective viewing solid angle of each viewpoint of the head-mounted/wearable game application scene is preferably 2.5-3.8, and the immersion feeling is stronger and can be further enhanced;

3) for the remote operation class application scenario:

the robot is remotely controlled to perform an operation scene, the effective viewing solid angle of each viewpoint is preferably 3-4, and the field optical environment is real;

the remote operation and control robot carries out field search and rescue operation scenes, the effective viewing solid angle of each viewpoint is further optimized to be 4-5.2, the real environment can be simulated to the greatest extent, and the feeling of being personally on the scene is created;

for the situation that one projector only provides one viewpoint, the SL is preferably between 0.000004 and 0.0025 square meters (4 square millimeters to 25 square centimeters), and the range can ensure that the projector is as small as possible under the situation of providing a complete window;

in the case that one projector provides two viewpoints, the light transmission area of the outermost lens is preferably between 49 square centimeters and 100 square centimeters, and the range can ensure that the projector is not particularly heavy;

further, for desktop application scenarios:

SP is preferably 0.04-1.2 square meters, L is preferably 0.2-1 meter, and the optimal balance between desktop space occupation and effective ornamental solid angle can be achieved;

for mobile-terminal application scenarios:

the SP is preferably 0.02-0.16 square meter, and the L is preferably 0.1-0.6 meter, so that the portability balance can be better considered, and further, the holographic screen can be made into a folding type or a scroll type;

for a wearable application scenario:

SP is preferably 4-50 square centimeters, L is preferably 5-12 millimeters, and the wearing requirement can be better met. Further, it may be arranged that two glasses share the same transmissive geometry hologram screen or one transmissive geometry hologram screen is separately provided for each glass, and in case that one transmissive geometry hologram screen is separately provided for each glass, SP is preferably set to 4cm²～12.8cm²It is appropriate that SP of 28cm is preferred for two glasses sharing the same transmissive geometry holographic screen²～50cm²Are suitable.

The foregoing is a more detailed description of the present invention, taken in conjunction with the specific preferred embodiments thereof, and it is not intended that the invention be limited to the specific embodiments shown and described. To the utility model belongs to the technical field of ordinary technical personnel, do not deviate from the utility model discloses under the prerequisite of design, can also make a plurality of simple deductions or replacement, all should regard as belonging to the utility model discloses a protection scope.

Claims (10)

1. A transmissive geometry holographic display system for optimizing display configuration, comprising:

at least one projector (1) for projecting picture information in space;

the transmission type geometric holographic screen (2) corresponds to the projector (1) in position and is used for optically converting the picture on one side to the other side to form an optical conjugate image;

a support structure (3) providing physical structural support for the projector (1) and the transmissive geometrical holographic screen (2); and

a controller (4) electrically connected to the projector (1), characterized in that:

the transmission type geometric holography display system with optimized display configuration comprises a plurality of viewpoints, the area of a single viewpoint is an SL square meter, the effective projection area of the transmission type geometric holography screen (2) is an SP square meter, the optical path distance between the center of the outermost lens of the single projector (1) and the center of the transmission type geometric holography screen (2) is L meters, and the effective viewing solid angle of each viewpoint meets the following requirements:

2. the transmissive geometry holographic display system of claim 1, in which: the maximum value L of the optical path distance L between the center of the outermost lens of the single projector (1) and the center of the transmission type geometric holographic screen (2)_MAXAnd a minimum value L_MINThe ratio of (A) to (B) satisfies:

3. the transmissive geometry holographic display system of claim 1, in which: the effective projection area SP of the transmission type geometric holographic screen ranges from 0.005 to 1.5 square meters.

4. The transmissive geometry holographic display system of claim 1, in which: the range of the single viewpoint area SL is 0.000004-0.5 square meter.

5. The transmissive geometry holographic display system of claim 1, in which: the optical path distance L between the center of the outermost lens of the single projector (1) and the center of the transmission type geometric holographic screen (2) ranges from 0.1 meter to 10 meters.

6. The transmissive geometry holographic display system of claim 1, in which: the optical path folding mirror group comprises at least one optical path folding mirror group (5) arranged on one side or two sides of the transmission type geometric holographic screen (2), wherein the optical path folding mirror group (5) at least comprises a plane mirror with a reflection function, and the plane mirror is used for changing the propagation path of the projection light of the projector (1).

7. The transmissive geometry holographic display system of claim 6, in which: the light path folding mirror group (5) is connected with the supporting structure (3).

8. A transmissive geometry holographic display system of optimized display configuration according to any of claims 1-7, wherein: the supporting structure (3) is a structure which can be deformed and/or moved, and is electrically connected with the controller (4).

9. The transmissive geometry holographic display system of claim 8, in which: the device is characterized by further comprising an interactive action capturing unit (6) electrically connected with the controller (4), wherein the interactive action capturing unit (6) is used for identifying the interactive action of the user and sending the interactive action information of the user to the controller (4), and the controller (4) adjusts the content of the display picture according to the received interactive action information of the user acquired by the interactive action capturing unit (6).

10. A transmissive geometry holographic display system of optimized display configuration of claim 9, in which: the display system is characterized by further comprising a human eye tracking unit (7) electrically connected with the controller (4), wherein the human eye tracking unit (7) is used for tracking the position of human eyes and sending the positioning information of the human eyes to the controller (4), and the controller (4) controls the supporting structure (3) to make corresponding action response according to the received human eye positioning information acquired by the human eye tracking unit (7) so as to adjust the space positions of all parts of the display system and enable the eyes of a user to be always in the visible space of the system.

Images