KR102513434B1 - Three-dimensional holographic waveguide-type augmented reality display system using holographic optical element micromirror-array - Google Patents

Abstract

The present invention relates to an augmented reality display system, and relates to a microdisplay for displaying an EIS (Elemental Image Set), and an in-coupler HOE-MA (In-coupler Holographic optical element Micromirror) for reconstructing the EIS displayed on the microdisplay into a 3D image. -array), the light information of the 3D image reconstructed by the in-coupler HOE-MA is input at the input end, and a waveguide for transmitting the input light information to the output end by total internal reflection without loss and the 3D image transmitted through the waveguide includes an out-coupler HOE (Out-coupler Holographic optical element) that allows the user to view by reflecting it to the user's viewing area and allows the light of an external real object to pass through to be viewed. According to the present invention, by providing a three-dimensional holographic waveguide type augmented reality display system using a holographic micro-mirror array, there is an effect of implementing the augmented reality display system simply and easily without the need for additional devices.

Description

Three-dimensional holographic waveguide-type augmented reality display system using holographic optical element micromirror-array}

The present invention relates to a head-mounted display technology for expressing augmented reality or virtual reality, and more particularly to a three-dimensional holographic waveguide type augmented reality display technology.

Augmented reality is a field of virtual reality and refers to a technology that synthesizes virtual objects or information in a real environment to make them look like objects existing in the original environment. That is, a virtual image is projected onto the real image the user is viewing and displayed to the user.

Through augmented reality technology, users can feel the direct sense of reality experienced in the objective physical world and experience experiences that cannot be experienced in the real world. Augmented reality is different from virtual reality in which real surroundings cannot be seen, and has significance in providing a better sense of reality and additional information through a mixture of real environments and virtual objects.

Augmented reality technology is a trend in which the range of applications is gradually expanding due to the rapid development of the technology and the recent spread of smartphones.

As one of the devices providing such augmented reality, there is a Head Mounted Display (HMD) which is worn on the head like glasses. The user can receive various multimedia contents through the HMD. When the HMD is combined with augmented reality technology or the like, various conveniences can be provided to the user beyond a simple display function.

Displays for augmented reality used in HMDs are mostly see-through type displays, and the user can overlap the virtual image generated by the computer and the real image through the see-through type display. augmented reality images can be provided.

See-through HMDs include an optical see-through HMD and a video see-through HMD. Among them, the optical see-through HMD uses a transflective optical combiner in front of the user's eyes, allowing the user to see the real world environment directly. Allows simultaneous viewing of virtual images projected by an optical synthesizer. Currently, a method for providing reference and supplementary data in augmented reality during precision work, work at the medical field, or surgery is being actively researched.

As such, the core equipment of Augmented Reality, Virtual Reality, and Mixed Reality systems is the head-mounted display. Among them, AR is applied to various application fields because users can observe computer-generated virtual objects in a real environment. can be made accessible.

Most conventional AR devices are designed to be bulky and heavy, and require various electronic and optical devices such as microcomputers, projectors, prisms, mirrors, microlenses, half mirrors, etc., and cause inconvenience to wear for a long time. Therefore, a highly portable and lightweight AR device is required.

Most AR HMDs use a waveguide structure.

A waveguide is an optical device that transfers a wave propagated by total internal reflection from an in-coupler to an out-coupler without loss of input information. It is a glass material with a specific thickness that transmits light between two different fields, the in-coupler and the out-coupler. It is an optical device composed of

In an AR HMD, light is transmitted from the micro-display to the observer's eyes.

Reflective, polarized, diffractive, and holographic waveguides have been proposed according to the characteristics of the in coupler and out coupler.

Among them, the holographic waveguide structure is more suitable for AR HMD because it can greatly reduce the size and weight because it can implement a waveguide in the form of a thin film. It also has the added advantage of being inexpensive and suitable for angles. The thin film replaced by the in coupler and the out coupler is a holographic optical element (HOE) manufactured by a hologram recording method. HOE is an optical film that obtains a desired wavefront by recording a hologram within an incident angle using laser light through an analog recording process.

Many optical elements and devices such as lenses or lens arrays, mirrors, prisms, etc., can be replaced by HOEs. Therefore, a holographic waveguide using two HOEs is very suitable as a main structure of an AR HMD.

However, this kind of AR system provides only two-dimensional (2D) images according to the properties of the HOE. Therefore, additional optical elements such as micro lens arrays are required to apply 3D images to holographic waveguide AR displays.

When these additional optical elements are applied to the holographic waveguide, the main drawback of existing AR displays is that they become larger in size and heavier in weight.

Korean Registered Patent No. 10-2182161

The present invention has been made to solve the above problems, and relates to the implementation of a 3D AR display that does not require an additional device. , The purpose is to provide a three-dimensional holographic waveguide type augmented reality display system using a holographic micromirror array.

The object of the present invention is not limited to the object mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

The present invention for achieving this object relates to an augmented reality display system, which includes a microdisplay for displaying an EIS (Elemental Image Set), and an in-coupler HOE-MA for reconstructing the EIS displayed on the microdisplay into a 3D image ( In-coupler Holographic optical element Micromirror-array), a waveguide for receiving light information of a 3D image reconstructed by the in-coupler HOE-MA at an input terminal and transferring the input light information to an output terminal by total internal reflection without loss. It includes an out-coupler holographic optical element (HOE) that reflects the 3D image transmitted through the waveguide to the user's viewing area so that it can be viewed, and allows light from an external real object to pass through and be viewed.

In the waveguide, the 3D image may be incident at an incident angle such that the light of the 3D image reaches the out-coupler HOE after being reflected once.

The in-coupler HOE-MA may be recorded by injecting a signal beam onto one side of the hologram recording medium and incident a reference beam on the other side of the hologram recording medium through a micro lens array.

According to the present invention, by providing a three-dimensional holographic waveguide type augmented reality display system using a holographic micro-mirror array, there is an effect of implementing the augmented reality display system simply and easily without the need for additional devices.

In addition, according to the present invention, there is an effect of improving the problem of increasing size and heavy weight, which is a disadvantage of existing AR displays.

1 is a conceptual diagram of a 3D holographic waveguide type augmented reality display system according to an embodiment of the present invention.
2 is a diagram schematically showing a configuration for in-coupler HOE-MA recording according to an embodiment of the present invention.
3 is a diagram schematically showing a configuration for out-coupler HOE recording according to an embodiment of the present invention.
4 is a photograph of a 3D holographic waveguide type augmented reality display system actually manufactured through the present invention.
5 is an enlarged photograph of an in-coupler HOE-MA and an out-coupler HOE actually manufactured through the present invention.

Advantages and characteristics of the embodiments disclosed in this specification, and methods for achieving them will become clear with reference to the embodiments described later in conjunction with the accompanying drawings. However, the embodiments to be proposed in the present disclosure are not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the present embodiments provide knowledge of the embodiments to those skilled in the art. It is provided only to give a complete indication of the categories.

Terms used in this specification will be briefly described, and the disclosed embodiments will be described in detail.

The terms used in this specification have been selected from general terms that are currently widely used as much as possible while considering the functions of the disclosed embodiments, but they may vary depending on the intention or precedent of a person working in the related field, the emergence of new technologies, and the like. In addition, in a specific case, there is also a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the detailed description of the corresponding specification. Therefore, the terms used in the present disclosure should be defined based on the meaning of the terms and the contents throughout the present specification, not simply the names of the terms.

Expressions in the singular number in this specification include plural expressions unless the context clearly dictates that they are singular.

When it is said that a certain part "includes" a certain component throughout the specification, it means that it may further include other components without excluding other components unless otherwise stated. Also, the term "unit" used in the specification means a hardware component such as software, FPGA or ASIC, and "unit" performs certain roles. However, "unit" is not meant to be limited to software or hardware. A “unit” may be configured to reside in an addressable storage medium and may be configured to reproduce on one or more processors. Thus, as an example, “unit” can refer to components such as software components, object-oriented software components, class components and task components, processes, functions, properties, procedures, subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays and variables. Functionality provided within components and "parts" may be combined into fewer components and "parts" or further separated into additional components and "parts".

In addition, in the description with reference to the accompanying drawings, the same reference numerals are given to the same components regardless of reference numerals, and overlapping descriptions thereof will be omitted. In describing the present invention, if it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

The present invention relates to a three-dimensional holographic waveguide-type augmented reality display system using a micro-mirror array of holographic optical elements.

1 is a conceptual diagram of a 3D holographic waveguide type augmented reality display system according to an embodiment of the present invention, and FIG. 4 is a photograph of a 3D holographic waveguide type augmented reality display system actually manufactured through the present invention. .

1 and 4, the augmented reality display system of the present invention includes a micro display 110, an in-coupler HOE-MA (In-coupler Holographic optical element Micromirror-array) 120, a waveguide ) 130, and an out-coupler holographic optical element (HOE) 140.

The micro display 110 displays Elemental Image Set (EIS).

The in-coupler HOE-MA 120 reconstructs the EIS displayed on the micro display 110 into a 3D image.

The waveguide 130 receives light information of a 3D image reconstructed by the in-coupler HOE-MA 120 at an input end, and transmits the input light information to an output end through total internal reflection without loss.

The out-coupler HOE 140 reflects the 3D image transmitted through the waveguide 130 to the user's viewing area 10 so that it can be viewed, and allows light of an external real object to pass through so that the augmented reality image can be viewed. to be displayed.

In the present invention, the 3D image may be incident at an incident angle such that light of the 3D image reaches the out coupler HOE 140 after being reflected once within the waveguide 130 .

In the present invention, the in-coupler HOE-MA 120 injects a signal beam onto one side of the hologram recording medium, and sends a reference beam through a micro lens array to the other side of the hologram recording medium. It can be recorded in a way that is incident on.

The 3D image reconstructed in the present invention is input to the waveguide 130 at an incident angle θ _i .

Incoherent light beams of the reconstructed 3D image reach the out-coupler 140 after being reflected once within the waveguide 130 .

In the present invention, the out coupler HOE 140 may be made of a transparent material, so that a 3D image can be reflected to the observer's eyes, and light reflected from an external real object can be seen through.

Here, since the light wave is propagated by total internal reflection of the waveguide 130, the incident angle θ _i must be greater than the critical angle θ _C. Therefore, θ _i is preferably 42° or more to provide a total internal reflection phenomenon.

In the present invention, the EIS is displayed on the micro display 110, the displayed light is incident to the in-coupler HOE-MA 120, and the reconstructed 3D image is reflected in the same direction from the waveguide 130 by total internal reflection. Here, the in-coupler HOE-MA 120 has a lens array and a mirror function at the same time.

2 is a diagram schematically showing a configuration for in-coupler HOE-MA recording according to an embodiment of the present invention.

In FIG. 2, NDF is a Neutral density filter, HWP is a Half wave plat, SF is a Spatial filter, ES is an Electrical shutter, CL is a Collimating lens, A is an Aperture, PBS is a Polarizing beam splitter, MLA is a Micro lens-array, and L is a Lens , M means a mirror, and HOE means a holographic optic element.

The recording sequence for manufacturing the HOE for the micro mirror array in the in-coupler HOE-MA is to place the micro lens array in the reference beam path for the reference beam and object beam separated through the PBS, and place the mirror in the path of the object beam. and record at the same time.

In the embodiment of Fig. 2, in the HOE's recording settings, the exposure time is set to 7-8 seconds for the procedure using the reference power, and the signal beam is adjusted equal to 1 mW/cm ² . The intensity ratio between the object and the reference beam is 1:6 because the incident light passes through each lens of the micro-lens array, reducing the incident light and being adjustable through half-wave.

In FIG. 2, the HWP serves to adjust the wavelength of the laser beam in the red, green, and blue wavelength bands passing through the NDF to 1/2.

The PBS serves to split the beam incident through the SF, ES, CL, and A (apertures) into two optical paths. If the first path and the second path are combined, the signal beam passes through the first path and the reference beam passes through the second path.

An optical mirror is positioned in the first path, and a micro lens array (MLA) is positioned in the second path.

In the in-coupler HOE-MA 120, a micro lens array (MLA) is recorded using a mask and an optical mirror is simultaneously recorded.

In the in-coupler HOE-MA 120, the HOE plate, which is a recording medium, is attached to and fixed to the waveguide, and a signal beam and a reference beam are combined in the waveguide by using two prisms.

3 is a diagram schematically showing a configuration for out-coupler HOE recording according to an embodiment of the present invention.

In FIG. 3, NDF is a neutral density filter, HWP is a half wave plat, SF is a spatial filter, ES is an electrical shutter, CL is a collimating lens, A is an aperture, PBS is a polarizing beam splitter, L is a lens, M is a mirror, and HOE is Means a holographic optic element.

The HOE plate, which is a recording medium of the out-coupler HOE 140, is attached and fixed to the waveguide, and a signal beam and a reference beam are combined in the waveguide using two prisms, and are used to connect them to the outside of the HOE.

In the embodiment of Fig. 3, the exposure time in the recording setting of HOE is set to 7-8 seconds for the procedure using the reference power, and the signal beam is adjusted equal to 1 mW/cm ² . The intensity ratio between the object and the reference beam is 1:6 because the incident light passes through each lens of the micro-lens array, reducing the incident light and being adjustable through half-wave.

In FIG. 3, the HWP serves to adjust the wavelength of the laser beam in the red, green, and blue wavelength bands passing through the NDF to 1/2.

The PBS serves to split the beam incident through the SF, ES, CL, and A (apertures) into two optical paths. If the first path and the second path are combined, the signal beam passes through the first path and the reference beam passes through the second path.

In the out-coupler HOE 140, the HOE plate, which is a recording medium, is attached to and fixed to the waveguide, and a signal beam and a reference beam are combined in the waveguide by using two prisms.

5 is an enlarged photograph of an in-coupler HOE-MA and an out-coupler HOE actually manufactured through the present invention.

The present invention has been described above using several preferred embodiments, but these embodiments are illustrative and not limiting. Those skilled in the art to which the present invention pertains will understand that various changes and modifications can be made without departing from the spirit of the present invention and the scope of rights set forth in the appended claims.

110 Microdisplay 120 Incoupler HOE-MA
130 Waveguide 140 Out Coupler HOE

Claims (3)

a micro display for displaying EIS (Elemental Image Set);
an in-coupler holographic optical element micromirror-array (HOE-MA) for reconstructing the EIS displayed on the microdisplay into a 3D image;
a waveguide for inputting light information of a 3D image reconstructed by the in-coupler HOE-MA at an input terminal and transferring the input light information to an output terminal by total internal reflection without loss; and
Including an out-coupler holographic optical element (HOE) that reflects the 3D image transmitted through the waveguide to the user's viewing area so that it can be viewed, and allows light of an external real object to pass through and be viewed,
The 3D image is incident on the waveguide at an incident angle θ _i such that the light of the 3D image reaches the out-coupler HOE after being reflected once, and the incident angle θ _i is 42° or more to provide a total internal reflection phenomenon in the waveguide. ego,
The in-coupler HOE-MA is recorded in such a way that a signal beam is incident on one side of the hologram recording medium and a reference beam is incident on the other side of the hologram recording medium through a micro lens array,
The in-coupler HOE-MA is a half wave plat (HWP) for adjusting the wavelength of a laser beam in the red, green, and blue wavelength bands that has passed through a neutral density filter (NDF) to 1/2, a spatial filter (SF), and an ES ( Electrical shutter), CL (Collimating lens), and PBS (Polarizing beam splitter) for separating the beam incident through A (Aperture) into two optical paths, and the two optical paths separated from the PBS. When the first path and the second path, the signal beam passes through the first path, the reference beam passes through the second path, the optical mirror is located in the first path, and the micro lens array (MLA) is located in the second path Is located, and the micro lens array (MLA) is recorded using a mask and the optical mirror is recorded at the same time,
In the recording for manufacturing the HOE for the micro mirror array in the in-coupler HOE-MA, a micro lens array is placed in a reference beam path for a reference beam and an object beam separated through a polarizing beam splitter (PBS), Simultaneous recording by placing a mirror in the path of the object beam, at this time, in the HOE's recording settings, the exposure time is set to 7-8 seconds for the procedure using a reference power, the signal beam is adjusted to 1 mW/cm 2 , and the object beam is adjusted to 1 mW/cm ² . The intensity ratio of the beam and the reference beam is 1:6,
The out-coupler HOE is a half wave plat (HWP) for adjusting the wavelength of a laser beam in the red, green, and blue wavelength ranges to 1/2 that has passed through a neutral density filter (NDF), a spatial filter (SF), and an electrical shutter (ES) ), a collimating lens (CL), and a polarizing beam splitter (PBS) for separating a beam incident through A (aperture) into two optical paths. If the first path and the second path are combined, the signal beam passes through the first path, the reference beam passes through the second path, the optical mirror is located in the first path, and the micro lens array (MLA) is located in the second path. ,
In the recording settings of the HOE in the above outcoupler HOE, the exposure time is set to 7-8 seconds for the procedure using reference power, the signal beam is adjusted to 1 mW/cm ² , and the intensity ratio of the object beam and the reference beam is 1: 6, characterized in that the augmented reality display system.
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