RU2721670C1 - System for expanding the area of the exit pupil of the visual optical system - Google Patents

Abstract

FIELD: optics.SUBSTANCE: invention relates to optical systems which make it possible to expand the area of exit pupil of visual optical systems. System comprises a waveguide and a diffraction grating made in the waveguide. At the same time radiation is divided by means of a diffraction grating into at least two radiation beams propagating along the waveguide at angles such that one of the at least two radiation beams comes out from the side of the waveguide surface opposite to the diffraction grating, and forms unit of exit pupil, other radiation beams undergo complete internal reflection from surface of waveguide, opposite to diffraction grating, and return to diffraction grating. Formed units of the exit pupil extend the area of the exit pupil of the visual optical system.EFFECT: universality, compactness, high diffraction efficiency of the system, possibility of expanding the area of the exit pupil while maintaining a high visual field of the optical system, providing homogeneity and brightness of the obtained image, enabling use of multispectral radiation.18 cl, 14 dwg

Description

Technical field

The present invention relates to optical systems, allowing to expand the area of the exit pupil of visual optical systems.

Description of the Related Art

Currently, visual optical systems, such as augmented reality systems, eyepieces and lenses of optical instruments (microscopes, telescopes, sights, etc.) are actively improving. The most important characteristic parameters of such visual optical systems are the magnitude of the field of view (FoV) and the size of the area of the exit pupil. An analysis of the prior art shows that in visual systems it is quite difficult to simultaneously provide a large field of view (for example, more than 60 degrees), a large exit pupil (for example, more than 3 mm) while ensuring the required quality or resolution of the image (for example, no worse than the limit angle of resolution of the eye, equal to 1 arc minute). In the prior art, devices for increasing the area of the exit pupil use complex elements, and the known devices are not universal; on the contrary, for each visual optical system, it is necessary to design a separate device for increasing the area of the exit pupil.

The exit pupil dilator disclosed in US 8508848 B2 (publication date Aug. 15, 2013) is known in the art. The expander is a waveguide, the radiation enters the waveguide using diffraction elements, propagates inside the waveguide and is output using diffraction elements. The known system allows you to expand the area of the exit pupil, but has a small width (limited value of the horizontal magnitude of the field of view) of the field of view and a complex structure having large overall dimensions. In addition, waveguide systems of this type give significant energy losses, since radiation is forced to propagate along large distances in the waveguide. In addition, such systems have limitations on the diffraction efficiency, uniformity and brightness of the resulting image, since for input and output radiation uses several diffraction elements.

The prior art US 6829095 B2 (publication date 05.16.2001) known optical beam expander, which is a waveguide system in which the radiation is displayed in the field of view using translucent mirrors. The size of the exit pupil is related to the geometrical parameters of the expander, such as the thickness of the waveguide and the number of mirror elements. The disadvantages of the known system are significant thickness, that is, sufficiently large overall dimensions, and design complexity. Also, using the known system it is impossible to obtain a sufficient field of view.

A universal system for expanding the area of the exit pupil is required, which can be integrated into any visual optical system and can provide a large area of the exit pupil along with maintaining a large field of view of the visual optical system, high diffraction efficiency, uniformity and brightness of the image.

SUMMARY OF THE INVENTION

A system is proposed for expanding the area of the exit pupil of the visual optical system, comprising: a waveguide; a diffraction grating located on the surface of the waveguide; moreover, the parameters of the diffraction grating are consistent with the parameters of the waveguide in such a way that: the diffraction grating is configured to: separate due to diffraction of radiation from the incident beams in the direction of propagation of at least two beams, one of which passes through the waveguide, refracting on its output surface and the second, reflected from this surface of the waveguide, again falls on the diffraction grating and is divided into at least two more beams, one of which again passes through the waveguide, refracting on its output surface, and the other continues to propagate in the waveguide, forming the next beams, thus, the set of multiplied rays after the waveguide forms the region of the exit pupil. That is, beams coming out of the waveguide that have not experienced total internal reflection in the waveguide after reflection from the output surface of the waveguide.

Moreover, the visual optical system can be one of the devices, which are: a microscope, telescope, sight, augmented reality device, a device in which the image is formed at infinity. Moreover, the diffraction grating is reflective. Moreover, the diffraction grating is transmission. Moreover, the diffraction grating may be a diffractive optical element. Moreover, the diffraction grating may be a holographic optical element. Moreover, the diffraction grating can be one-dimensional. Moreover, the diffraction grating may be two-dimensional. Moreover, the waveguide may have a curved shape. Moreover, the diffraction grating may be a Bragg grating.

A visual optical system is also provided comprising a system for expanding the area of the exit pupil in all of the disclosed embodiments. Moreover, the system for expanding the area of the exit pupil can be located at the output of the visual optical system. Moreover, the visual optical system emits multispectral radiation. Moreover, the visual optical system can emit monospectral radiation. Moreover, the system for expanding the area of the exit pupil can work in light. Moreover, the system of expanding the area of the exit pupil can work on reflection.

Also proposed is a method of operating the system for expanding the area of the exit pupil of the visual optical system, comprising the steps of: supplying radiation beams from the visual optical system to the system of expanding the area of the exit pupil; due to the diffraction of each of the radiation beams incident on the diffraction grating from the visual optical system, at least two diffraction orders are formed so that: one of the at least two diffraction orders comes out from the side of the waveguide surface opposite to the diffraction grating and forms an output unit pupil of the visual optical system; while the remaining radiation beams: undergo complete internal reflection from the surface of the waveguide opposite the diffraction grating, and return to the diffraction grating, each of the radiation beams returning to the diffraction grating is separated by means of the diffraction grating into at least two radiation beams, one of which comes out from the side of the waveguide surface opposite the diffraction grating, forming a unit of the exit pupil of the visual optical system; moreover, the formed units of the exit pupil of the visual optical system form a set of multiplied rays in the area of the exit pupil of the visual optical system.

Brief Description of the Drawings

The above and other features and advantages of the present invention are explained in the following description, illustrated by the drawings, in which the following is presented:

FIG. 1 illustrates the telecentric path of rays in object space.

FIG. 2a illustrates the course of rays in the proposed system for expanding the area of the exit pupil.

FIG. 2b illustrates the path of rays from an object to the exit pupil region of the visual optical system using the exit pupil region expansion system, and the formation of the expanded exit pupil region.

FIG. 2c illustrates the operation of the exit pupil area expansion system for reflection.

FIG. 3a illustrates the heterogeneous (discrete) filling of the exit pupil area.

FIG. 3b illustrates the uniform filling of the exit pupil area.

FIG. 4 illustrates a spatial diagram of an augmented reality device in which the proposed system for expanding the area of the exit pupil is used, wherein the HOE combiner and diffraction grating operate in light.

FIG. 5a shows a translucent HOE combiner comprising a system for expanding an exit pupil region with a reflection diffraction grating.

FIG. 5b shows a reflective HOE combiner comprising a system for expanding the exit pupil region with a diffraction grating operating in light.

FIG. 6 illustrates the use of a one-dimensional diffraction grating in an exit pupil region expansion system.

FIG. 7 illustrates the use of a two-dimensional diffraction grating in an exit pupil region expansion system.

FIG. 8 illustrates a system for expanding an exit pupil region in which a diffraction grating is located inside a waveguide.

FIG. 9a illustrates the appearance of stray light in the exit pupil area.

Figure 9b illustrates a system for expanding the area of the exit pupil having a curved shape.

DETAILED DESCRIPTION OF THE INVENTION

The problem to which the invention is directed is to create a system for expanding (multiplying) the area of the exit pupil, which has low energy losses from the radiation incident on it, is compact, universal, and easily integrated into any visual optical system.

The technical results to which the invention is directed are:

universality, compactness, high diffraction efficiency of the proposed system for expanding the area of the exit pupil,

the possibility of expanding the area of the exit pupil along with maintaining a large field of view of the visual optical system,

ensuring uniformity and brightness of the resulting image,

the possibility of using multispectral radiation.

To solve this problem and achieve technical results, a compact system is proposed for expanding the area of the exit pupil based on a waveguide with one diffraction grating, which is either a diffractive optical element (DOE) or a holographic optical element (HOE), and one diffraction grating is used as for radiation input so for output radiation.

The proposed system can be used to expand the area of the exit pupil of visual optical systems such as, for example, eyepieces of optical instruments. As you know, the eyepiece of the optical system is an element of the optical system facing the eye of the observer, the eyepiece is part of an optical device (viewfinder, range finder, binoculars, microscope, telescope, and so on) designed to view the image formed by the lens or the main mirror of the device. The proposed system for expanding the area of the exit pupil is installed in a visual optical system, or an augmented reality device (AR) with an image combiner (combiner) using HOE / DOE, combining the image of the environment and the image created by the internal display, etc.

The proposed system for expanding the area of the exit pupil is compact and universal, moreover, compactness and versatility is determined by using only one DOE / HOE element) for input and output radiation, and the waveguide used in the proposed system should not have high quality. Due to the proposed design, the overall dimensions of the system for expanding the area of the exit pupil are noticeably reduced, that is, the proposed system can be used in various optical systems, without changing the overall dimensions of these visual optical systems.

The exit pupil of the visual optical system is the area within which the observer sees the image. In other words, the exit pupil is a paraxial image of the aperture diaphragm in the image space, formed by the next part of the optical system in the direct course of the rays. This term is well-established in optics. The main property of the exit pupil of the visual optical system is that at any point there is an entire image field. By multiplying (expanding, multiplying) the exit pupil, thereby increasing its size, without resorting to increasing the longitudinal dimensions of the visual optical system. Classical optics allows you to increase the size of the exit pupil, but at the same time, the longitudinal dimensions of the visual optical system increase. The use of waveguide optics allows this to be done without a significant increase in the dimensions of the visual optical system due to the multiple reflection of beam beams inside the waveguide.

The area of the exit pupil is understood as the area accessible to the pupil of the human eye from any position of the pupil of the eye (with the displacement of the pupil of the eye).

By the magnitude of the field of view is meant the angular space visible by the eye with a fixed position of the pupil and the immovable head. When the magnitude of the field of view is large, the eye can see most of the space of objects. However, when the pupil is displaced, for example, by a few millimeters to the side, the field of view is cut off, and it seems that the magnitude of the field of view has decreased. This is due to the fact that the region of the exit pupil of the visual optical system is small, and when the pupil of the eye is displaced, this region does not completely fall into the pupil of the eye or does not fall at all.

By diffraction efficiency is meant a property of the diffraction grating, measured in percent or fractions of a unit, and is the ratio of the energy contained in one of the diffraction orders relative to the energy incident on the diffraction grating.

The figure 1 schematically shows the telecentric path of the rays in the object space, using a visual optical system 2 (in figure 1, the visual optical system 2 is shown conditionally) in the General case, without using the proposed system to expand the area of the exit pupil.

The size of the visual field of the visual optical system is calculated by the formula:

(1)

(1)

The size of the exit pupil of the visual optical system is calculated by the formula:

(2)

(2)

S is the size of the object (expressed in millimeters);

F is the focal length of lens 2 (expressed in millimeters);

FoV - the magnitude of the field of view of the system (expressed in degrees);

E is the size of the area of the exit pupil (expressed in millimeters);

Le is the distance from the lens 2 of the visual optical system to the pupil 1a of eye 1 (expressed in millimeters);

D is the aperture size of the lens 2 of the visual optical system (expressed in millimeters);

It follows from formulas (1) and (2) that without using the proposed system of expanding the exit pupil region with the visual optical system 2, the size E of the exit pupil region is limited by the FoV field of view, which, in turn, is limited by the focal length F of the visual optical system and the size S of the object. The larger the area of the space of objects (that is, the object) the user wants to see, the greater the FoV value of the field of view should be. The focal length F of the visual system 2 must also be small so that the system is compact, which is necessary, for example, in augmented reality glasses. According to formulas (1) and (2), in the general case, there is an inverse relationship between the magnitude FoV of the field of view and the magnitude E of the area of the exit pupil. In the ordinary visual optical system 2, it is impossible to achieve both a large FoV of the field of view and a large value of E of the area of the exit pupil without the use of additional elements. Such a universal and compact additional element is the proposed system for expanding the area of the exit pupil.

A key element of the proposed system for expanding the area of the exit pupil is the waveguide diffraction grating, when using which diffraction orders exist only in the waveguide (they are not in free space). The diffraction grating must be designed for specific angles of incidence of radiation on this grating. These angles of incidence are determined by the aperture angle of the visual optical system. In other words, rays come out of the visual optical system at certain angles to the optical axis, then they fall on the grating at these angles. The diffraction grating for the exit pupil area expansion system must be designed so that there are only three diffraction orders “0” (zero), “–1” (minus the first) and “+1” (first), and that these diffraction orders propagate in the waveguide material.

(3)

(3)

n1 is the refractive index in front of the system for expanding the area of the exit pupil;

n2 is the refractive index of the waveguide;

M is the number of diffraction orders;

d is the lattice period;

ϴ - angles of incidence of radiation on a given grating, namely ϴ ₁ - angle of incidence on a grating, ϴ ₂ - angle of diffraction - angle by which radiation inside the waveguide is deflected for the Mth order;

λ is the wavelength of radiation incident on the diffraction grating;

T is the frequency of the diffraction grating — the reciprocal of the period T = 1 / d, (stroke / mm), if d is expressed in mm)

According to formula (3), a plane diffraction grating is calculated for the problem of expanding the area of the exit pupil. The selection of the parameters of the diffraction grating, such as the grating period (constant or variable), the relief depth, the type of profile (strokes), the orientation of the strokes, takes place under the specific function that the diffraction grating in the device should perform, in this case, the function is to expand the area of the exit pupil . The parameters of the diffraction grating depend on:

- angles of incidence of the radiation from the visual optical system onto the diffraction grating,

- the material of the waveguide on which the diffraction grating is located,

- the required size of the area of expansion of the exit pupil.

It should be noted that the functional of the diffraction grating is determined by:

- for the holographic recording method by the configuration of the recording circuit, the spatial arrangement of the recording sources relative to each other and the ratio of their radiation powers;

- for the lithographic method of recording a previously known structure of the diffraction grating, determined from modeling and calculation.

According to preliminary theoretical and computer modeling, the lattice and waveguide parameters must be consistent so that the combination of these elements works to expand the area of the exit pupil.

That is, for the system of expansion of the exit pupil area, the diffraction grating parameters are calculated so that there are only three diffraction orders “0” (zero), “–1” (minus the first) and “+1” (first), and that these orders diffraction propagated in the material of the waveguide with at least one reflection from the surface of the waveguide under the condition of total internal reflection (TIR), excluding the zero diffraction order. Radiation contained in the zeroth order undergoes refraction at the boundary of the waveguide material and air and leaves the expander.

A key element of the proposed system for expanding the area of the exit pupil is the waveguide, which allows to obtain a waveguide mode of propagation of incident radiation. Achieving the waveguide regime consists in observing the condition under which the angle of incident radiation from “–1” and “+1” diffraction orders is equal to or greater than the angle of total internal reflection (TIR). There is a relationship between the parameters of the waveguide and its functional; in the best version, the waveguide should be thin so that the radiation emerging from it is uniform, then the area of expansion of the exit pupil will be more uniform.

Thus, in order to obtain the property of expanding the area of the exit pupil, the parameters of the waveguide and the diffraction grating must be consistent in order to obtain such a new property of expanding the range of the exit pupil.

Methods for creating diffraction gratings are well known in the art, for example, relief diffraction gratings are applied by etching through masks or nanoimprinting, holographic diffraction gratings are recorded by an interference pattern, etc.

In the present invention, both a planar waveguide and a non-planar waveguide on which a diffraction grating is recorded / applied can be used.

It should be noted that the diffraction grating is generally performed on a waveguide in the manufacture of a system for expanding the area of the exit pupil. To obtain the effect of multiplying the rays incident on such a system without changing their properties, the parameters of the diffraction grating and the waveguide must be agreed upon during manufacture. Recording takes place on a substrate on which photoresistive material is applied. This substrate can already essentially perform the function of a waveguide, then the lattice is recorded immediately on the substrate from the desired material and the desired thickness, that is, designed for a visual optical system in which it is planned to use the expansion system of the exit pupil area, and the parameters of this substrate are consistent with the parameters recorded on her diffraction grating. Or, after recording on a photoresistive material, the resulting lattice relief is displayed and copied, transferring this relief to the photopolymer, essentially a thin film. Next, the photopolymer is applied in any known manner to the desired waveguide. In this case, the parameters of the waveguide and the grating should be consistent, as described above, which allows us to solve the problem of expanding the area of the exit pupil.

In manufacturing, the system for expanding the area of the exit pupil is calculated for specific incidence angles determined by the aperture angle of the visual optical system. The same exit pupil area expansion system can be integrated and work correctly in different visual optical systems if the aperture angle of these visual optical systems does not exceed or equal the aperture angle for which the exit pupil area expansion system was calculated, this determines the universality of the proposed system expanding the area of the exit pupil. That is, the system for expanding the area of the exit pupil has an angular range in which it can function correctly. This range is the size of the output aperture angle of the visual optical system.

Example.

The exit pupil expansion system was designed for a system with an aperture angle of 60 °. Such a system for expanding the area of the exit pupil can also be used in a system with an angular field of less than 60 ° (for example, 40 °). But if the visual optical system has a field greater than 60 °, then the system for expanding the area of the exit pupil with an aperture angle of 60 ° cannot be used in this system, since it will function incorrectly.

In FIG. 2a shows the course of the rays in the proposed system 5 to expand the area of the exit pupil. In FIG. 2b shows the use of the exit pupil region expansion system 5 for expanding the exit pupil region 7 (FIG. 2b) of the visual optical system 2 (FIG. 2b). The radiation from the visual optical system (Figs. 2a and 2b show a thin parallel beam a and a thin parallel beam b for clarity), hitting the diffraction grating 3 propagates in three directions, and “0” (zero), “–1” are formed ( minus the first) and “+1” (first) diffraction orders.

 The “0” diffraction order, having passed through the waveguide 4, completely leaves the waveguide 4 from the side of the surface 6 opposite to the surface on which the diffraction grating 3 is deposited, without being reflected from the surface 6, since it does not satisfy the condition of total internal reflection (AA). A set of “0” diffraction orders from each parallel beam a and b is collected, as shown in FIG. 2b in the region of the pupil of the eye 1a and, as shown in FIG. 2a, forms the 1st unit of the exit pupil of the entire area 7 of the exit pupil, which is circled in FIG. 2b with a circle and shown in FIG. 2a, as the "1st unit."

The diffraction order “–1” passes in the waveguide 4 to the surface 6 opposite to the surface on which the diffraction grating 3 is deposited and, due to total internal reflection (IR), is reflected from the surface 6, passes through the waveguide 4 back to the diffraction grating 3, since it satisfies air defense condition. Once on the diffraction grating 3, the diffraction order “–1” is divided into parts. It should be noted here that, as mentioned above, the diffraction grating is designed in such a way that when a beam is incident on it at a certain angle γ, this beam is decomposed into three diffraction orders, that is, “0” leaves the waveguide, “+1” and “–1” - they are deflected by an angle α inside the waveguide and after passing the waveguide the radiation from “+1” and “–1” orders of magnitude falls on the same diffraction grating at an angle α, therefore, according to the properties of the diffraction grating, it will deflect incident at an angle α beam, at an angle γ, while there will be no other orders in the case of incidence at an angle α on the lattice. That is, a distributed interaction of radiation with a diffraction grating occurs, which is characteristic of the waveguide propagation mode. The output rays in this interaction exactly correspond to the incident rays, that is, spatially at the output of the system the same waves are obtained that were at the input of the system. So, one part of the diffraction order “–1” departs from the diffraction grating 3 and for this part the air defense condition is violated, therefore this part extends from the side of surface 6. This part of the radiation emerging from the waveguide 4 will participate in the formation of the second unit of the exit pupil. The other part of the diffraction order “–1” diffracts on the grating 3 and the radiation continues to propagate in the waveguide, as can be seen in figure 2a. After the second reflection from surface 6, part of the radiation is again diffracted by the diffraction grating, the air defense condition is again violated, and the next emerging part of the radiation will participate in the formation of the 4th unit of the exit pupil (not shown in figure 2b). The same is true for the order “+1”, from which, in particular, the 3rd unit of the exit pupil is formed, as shown in FIG. 2a and 2b.

As can be seen from FIG. 2b, the exit pupil region 7 (circled for clarity) is a set of exit pupil units. The number of exit pupil units may be any necessary for the device used. The number of exit pupil units is selected depending on

a) the value of the obtained pupil unit without a system for expanding the area of the exit pupil;

b) the required area of the exit pupil for the correct operation of the visual optical system.

Thus, by changing the parameters of the diffraction grating and the waveguide, that is, the parameters of the system for expanding the area of the exit pupil, it is possible to achieve the required number of units of the exit pupil for the necessary increase (expansion) of the area of the exit pupil .

The number of exit pupil units (the degree of animation) is governed by the thickness of the waveguide and the diffraction angles. The distance between the units of the exit pupil is determined by the thickness, the material of the waveguide. The radiation intensity in each unit of the area of expansion of the exit pupil depends on the diffraction intensity of the grating. A correctly calculated and simulated system for expanding the area of the exit pupil allows you to get a predetermined number of units of the exit pupil. Thus, it is possible to control the degree of animation already at the stage of manufacturing a system for expanding the area of the exit pupil.

The waveguide materials for the proposed system for expanding the area of the exit pupil can be, for example, optical colorless glass, the refractive index of which is selected depending on how many units of the exit pupil you need to get, the higher the refractive index (flint grades of glass), the greater the angle of air defense, the further apart the exit pupil units will be spaced apart. The lower the refractive index (crown grades of glass), the smaller the angle of defense, the closer the exit pupil units will be located to each other).

The described principle of radiation propagation is observed for each individual thin parallel beam of radiation (beams a and b in figures 2a and 2b) incident on the proposed system 5 to expand the area of the exit pupil.

It should be noted that the proposed system 5 of expanding the area of the exit pupil is not sensitive to displacements (in Fig. 2b, the offset is indicated as “var”) relative to the visual optical system 2 and to rotation relative to the optical axis 8 (sight axis), since the change in distance is “var” does not affect the angles of incidence of the radiation from the visual optical system 2 to the system 5 of expansion of the exit pupil area, namely, the further behavior of the radiation in the expander — diffraction by the grating — depends on the mentioned angles. On the other hand, visual optical systems, into which the system of expanding the exit pupil area is integrated, form an image at infinity. Rotation around the optical axis also does not affect the mentioned angles of incidence. The parameters of the system for expanding the area of the exit pupil are calculated at the angles of incidence, which are determined by the visual optical system, these angles are in the range of the aperture angle.

The expansion (multiplication or repetition) of the area of the exit pupil in the most general case occurs as follows (shown in Fig. 2b). An object is examined using a visual optical system 2, for example, such as an augmented reality device, or the eyepiece of a microscope, telescope, sight, etc., whereby the image of the object is directed to the eye 1, on the retina of which an image of this object is built. That is, a parallel beam of rays reflected from the object passes through the visual optical system 2 and, getting into the pupil 1a, focuses on the retina 1. To expand the area of the exit pupil of the visual optical system 2, the output of the visual optical system 2 is set along the parallel beam of rays the proposed system 5 of expanding the area of the exit pupil, which divides the parallel beam of rays into at least two parallel beam of rays, each of which is involved in the formation of a separate unit of the exit pupil, thereby increasing (expanding) the area of the exit pupil of the visual optical system 2.

The proposed system for expanding the area of the exit pupil can be used with optical devices (visual optical systems) that build an image ranging from the distance of the best view to infinity. In FIG. 2b shows the proposed exit pupil area expansion system 5 integrated into the visual optical system 2.

The advantage of the waveguide mode is that the loss of radiation propagating in the waveguide is very small. Thus, since the diffraction grating in the proposed system is used both for input and output of radiation and the waveguide mode is used, the radiation loss is reduced to almost zero, i.e., all radiation from the visual optical system is involved in the formation of exit pupil units that make up the exit pupil area pupil. In addition, there should be a parallel beam at the output of the visual optical system, since the eye is the radiation receiver. A parallel beam should enter the eye, which is focused by the lens (essentially a collecting lens) on the retina, and the person clearly sees the object. If a non-parallel beam is formed at the output of the visual optical system, the image on the retina of the eye will be blurred. That is, the image will not be built on the retina, but in front of the retina or behind the retina. After radiation in the form of parallel beams from the visual optical system passes through the proposed system for expanding the area of the exit pupil, the radiation beams remain parallel.

The proposed system 5 of expanding the area of the exit pupil can be used for visual systems that use both monospectral radiation and multispectral radiation, which forms a color image, since one diffraction grating is used to input radiation into the waveguide and to output radiation from the waveguide, and the conditions of the waveguide mode. That is, the input and output radiation, as described above, are consistent, i.e. what was input is multiplied without changing its properties.

It should be noted that the proposed system for expanding the area of the exit pupil can operate as a lumen, as described above and shown in FIG. 2b and reflection.

In FIG. 2c schematically shows the operation of the system 5 of expanding the area of the exit pupil to reflect the diffraction grating. The principle of operation is as follows:

The input radiation (parallel beam of rays) from the visual optical system 2 falls on the surface 6 of the waveguide 4, opposite the surface of the waveguide 4, on which the diffraction grating 3 is deposited.

Refracted in the waveguide 4, a parallel beam of rays falls at an angle on the diffraction grating 3 of the reflective type.

A beam of rays hitting a reflective diffraction grating 3 propagates in three directions, while “0” (zero), “–1” (minus the first), and “+1” (first) diffraction orders are formed.

The “0” diffraction order, having passed through the waveguide 4, completely leaves the waveguide 4 from the side of the surface 6, without being reflected, since it does not satisfy the condition of total internal reflection (TIR).

A set of “0” diffraction orders from each parallel beam of radiation is collected in the region of the pupil of the eye 1a and forms the 1st unit of the exit pupil of the entire region of the exit pupil (similar to the system’s work in the light).

 “+1” and “–1” diffraction orders satisfy the air defense condition and propagate in the waveguide mode (as was described for a system operating in transmission).

After the first reflection from the surface 6 of the waveguide 4, parts of the radiation from the “+1” and “–1” diffraction orders again fall on the diffraction grating 3, the air defense condition is violated, and the radiation beams emerging from the waveguide 4 participate in the formation of additional units of the exit pupil. In this case, part of the radiation from these orders continues to propagate in waveguide 4.

After the second reflection from the surface of the waveguide 6, part of the radiation again falls on the diffraction grating 3, the air defense condition is violated, and the beams emerging from the waveguide 4 participate in the formation of additional units of the exit pupil (as was described for the system to work in the light). Part continues to propagate along waveguide 4.

As well as for the operation of the system for expanding the area of the exit pupil into the lumen, the area of the exit pupil is a set of units of the exit pupil. As mentioned above, the number of units of the exit pupil can be any, that is, one that is necessary for the used visual optical system, which allows you to adjust the degree of animation. As you can see the principle of radiation propagation in the expansion system of the area of the exit pupil, which uses a reflective diffraction grating, is similar to the propagation principle discussed above and shown in figures 2a and 2b, where a diffraction grating operating in light was used, the only difference is in the orientation of the expansion system areas of the exit pupil along the rays of the visual optical system. In the case of the use of a diffraction grating operating in the light, the radiation first passes through the diffraction grating 3, and the region of the exit pupil is formed behind the system 5 of expansion of the region of the exit pupil (see Fig. 2b). In the case of using a reflective diffraction grating 3, the radiation first passes through the waveguide 4, refracting, and enters the diffraction grating 3, and the exit pupil region is formed in front of the exit pupil expansion system 5 (see Fig. 2c).

The experiments show that due to the application of the proposed exit pupil area expansion system for the visual optical system, the exit pupil area can be increased by more than five times in comparison with the exit pupil area of the visual optical system, in which the proposed exit pupil area expansion system was not used. the field of view of the visual optical system does not decrease. In addition, since in the proposed system for expanding the region of the exit pupil, the radiation propagates over very short distances in the waveguide, the radiation energy loss is minimal.

The high diffraction efficiency of the proposed system for expanding the area of the exit pupil allows you to perform a uniform filling of the area 7 of the exit pupil.

In FIG. 3a shows a non-uniform (discrete) filling of the exit pupil region 7. With such filling of the exit pupil region 7 with parallel beams 9 that have passed through the visual optical system 2, “blind zones” 10 are formed, that is, zones where the eye does not see the boundaries of individual units of the exit pupil region, since there is no exit pupil unit in this zone . The resolution of the exit pupil area depends on two parameters:

- from the diffraction angle of the diffraction grating 3 (i.e., the angle of input of radiation into the waveguide) and

- from the thickness and material of the waveguide (that is, from the angle of total internal reflection).

By combining these two parameters, one can control the frequency of reflections in waveguide 4 and ultimately influence the degree of discreteness. As shown in FIG. 3b, when there are a lot of exit pupil units, that is, when the exit pupil region 7 is filled with a set of exit pupil units 11, the discreteness disappears, and the exit pupil region becomes homogeneous.

In order for the image to be uniform, the radiation energy in each unit of the exit pupil must be the same, otherwise in one position the eye will see a very bright image, and in another position the eye will see a very dim image.

Equalization of the radiation energy in each unit of the exit pupil is achieved by optimizing the parameters of the diffraction grating 3, for this, during the manufacturing, the period of the diffraction grating is selected so that the rays at the entrance to the expansion system of the area of the exit pupil and at the exit from it are matched, while the height of the relief of the grating is selected so that each unit of the exit pupil is uniformly bright and one-dimensional. The system for expanding the area of the exit pupil has an angular range in which it can function correctly. This range is the size of the output angular field of the visual system.

Example.

The system of dilating the area of the exit pupil is designed for a visual optical system with an angular exit field of 60 °. Such a system for expanding the area of the exit pupil can also be used in a system with an angular field of less than 60 ° (for example, 40 °). But if the visual optical system has a field greater than 60 °, the considered system of expanding the area of the exit pupil can no longer be applied in such a system, since the system of expanding the area of the exit pupil in this case will not function correctly.

The figure 4 shows a spatial diagram of the device of augmented reality, which uses the proposed system to expand the area of the exit pupil.

The radiation from the source F of the image falls on the combiner 12, combining the image of the environment and the image created by the source F of the image (for example, an internal display). The combiner 12 forms the magnitude of the field of view of the augmented reality device and redirects the radiation to the expansion system 5 of the exit pupil region 7. The exit pupil region expansion system 5 expands the exit pupil region 7 of the augmented reality device as described above. It should be noted that the various zones (a, b, c, d in Fig. 4) of the exit pupil area expansion system 5 redirect the radiation into the eye 1 at various angles, completely and uniformly filling the exit pupil region 7 with the totality of exit pupil units 11 obtained for due to the passage of radiation from the augmented reality system through the proposed system 5 of expanding the area of the exit pupil. In this case, the system of expanding the area of the exit pupil for the augmented reality device is two-dimensional, since a two-dimensional diffraction grating is used, that is, the expansion of the area of the exit pupil is possible in two mutually perpendicular directions, but in the same plane.

It is known that combiners based on a holographic optical element (HOE combiner) have a small exit pupil area, therefore, to expand the exit pupil area of such a combiner, it is useful to use the proposed exit pupil area expansion system 5.

Figures 5a and 5b show the integration of the system 5 of expanding the area of the exit pupil into the device of augmented reality glasses with a HOE-combiner (combiner) 13.

Figure 5a shows a NOE-combiner 13 operating in light. The image is built behind the NOE-combiner 13, that is, from the opposite side with which the NOE-combiner 13 is highlighted. The exit pupil area expansion system 5 is installed behind the NOE-combiner 13, which is closer to the eye 1. The radiation from the image source F is incident on the NOE-combiner 13, and the field of view of the system is formed by inclined parallel beams, then the beams fall into the output area expansion system 5 pupil, there is the formation of additional units of the exit pupil, as described above. The rays pass a second time through the NOE-combiner 13 without interacting with the NOE-combiner 13, while the NOE-combiner 13 does not affect the course of these already multiplied rays.

Figure 5b shows a NOE-combiner 13 operating on reflection, that is, the image is built in front of the NOE-combiner 13, on the same side as the backlight of the NOE-combiner 13. In this case, the system 5 to expand the area of the exit pupil is installed in front of the NOE-combiner 13 and at the same time, the exit pupil area expansion system is closer to the eye 1 Also, the NOE-combiner 13 first forms a field of view, then the exit pupil area is expanded using the exit pupil area expansion system 5 due to the formation of an additional exit pupil unit.

Since the proposed system for expanding the area of the exit pupil has compact dimensions, it is easy to integrate it into an augmented reality device, practically without changing the overall dimensions and weight of the augmented reality device.

In the case of using a one-dimensional diffraction grating, as shown in FIG. 6 in the system for expanding the area of the exit pupil, the radiation from the visual optical system 2 enters and diffracts onto the one-dimensional diffraction grating 3. Passed and diffracted rays lie in the same plane. As described above, “0” the diffraction order passes, “+1” and “–1” diffraction orders propagate along the X axis along the waveguide 4 due to the ADR phenomenon, again fall on the diffraction grating 3, the ADR condition is violated, and the rays exit the system 5 of the expansion of the exit pupil region, forming additional units of the exit pupil along one X axis, that is, the exit pupil region 7 of the visual optical system expands in only one direction.

Unlike a one-dimensional diffraction grating, in a two-dimensional diffraction grating, strokes are plotted in two orthogonal directions. In the case of using a two-dimensional diffraction grating in the expansion system of the exit pupil area, as shown in FIG. 7, the radiation from the visual optical system 2 enters the two-dimensional diffraction grating 3 and diffracts on it in two directions (along X and Y). The principle of operation is further repeated, as for a one-dimensional diffraction grating, only the expansion of the exit pupil region 7 occurs in two directions, and the exit pupil region 7 expands not in one coordinate, but in two.

In one embodiment, as shown in FIG. 8, the diffraction grating 3 can be located inside the waveguide 4. In this case, the radiation diffracts on the diffraction grating 3 located inside the waveguide 4, and is divided into two parts. One part of the radiation propagates in part a of the waveguide 4, located along the rays after the diffraction grating 3, then again falls on the diffraction grating 3, the air defense condition is violated, the radiation leaves the system 5, and units of the exit pupil are formed, as in the case of the location of the diffraction gratings 3 on the surface of waveguide 4. Another part of the radiation also experiences diffraction on grating 3, but propagates in part b of the waveguide located along the rays to grating 3, then diffracts again on grating 3, and additional units of the exit pupil are formed, allowing more uniformly fill the area 7 of the exit pupil.

и паразитная засветка под углом

, то дифракция будет в обоих случаях, причем от паразитной засветки не будет единиц выходного зрачка, будет видно «радужное» пятно (рис. 9а). Такое явление может наблюдаться при использовании системы расширения области выходного зрачка в очках дополненной реальности с небольшой областью выходного зрачка. В этом случае, как показано на фигуре 9a, если сквозь визуальную оптическую систему будет виден дополнительный источник освещения (например, уличный фонарь, фара автомобиля и др), то излучение от этого дополнительного источника будет претерпевать дифракцию (но не мультипликацию) и появиться посторонняя засветка (в виде спектра («радуги»), например). Figure 9b shows that the system 5 to expand the area of the exit pupil can be a curved waveguide 4 with a diffraction grating 3 (DOE / HOE) deposited on it. Due to the change in the shape of the system for expanding the area of the exit pupil, system 5 will only work for a certain angle of incidence, at which the curvature of system 5 should be calculated, that is, selectivity is made according to the angle of incidence. As shown in FIG. 9a, if rays at different angles, for example, useful radiation at an angle, fall on a conventional non-curved diffraction grating 3 on a plane waveguide 4

and spurious illumination at an angle

, then there will be diffraction in both cases, and there will be no units of the exit pupil from parasitic exposure, a “rainbow” spot will be visible (Fig. 9a). This phenomenon can be observed when using the system for expanding the area of the exit pupil in augmented reality glasses with a small area of the exit pupil. In this case, as shown in figure 9a, if an additional light source (for example, a street lamp, a car headlight, etc.) is visible through the visual optical system, the radiation from this additional source will undergo diffraction (but not animation) and an extraneous illumination will appear (in the form of a spectrum (“rainbow”), for example).

, будут всегда направлены перпендикулярно поверхности волновода, поскольку у волновода появится дополнительный параметр, а именно – кривизна, который можно изменять и подбирать нужным образом под требуемый диапазон падающих углов (диапазон падающих углов задан визуальной системой, в которой планируется применение расширителя), следовательно, только для одного угла падения

будет осуществляться расширение области 7 выходного зрачка. In the case of a curved waveguide 4 shown in FIG. 9b, rays incident at a useful angle

will always be directed perpendicular to the surface of the waveguide, since the waveguide will have an additional parameter, namely, the curvature, which can be changed and selected as needed for the desired range of incident angles (the range of incident angles is set by the visual system in which the expander is planned to be used), therefore, only for one angle of incidence

will expand the area 7 of the exit pupil.

In the case of using a waveguide 4 having a curved shape, Bragg gratings can be used. Their advantage is that they have high diffraction efficiency, they are selective in angle and wavelength. Bragg diffraction gratings can also be used in the case of a planar waveguide, if it is necessary to increase the efficiency of radiation incident at an angle (at the edge of the angular field of the visual system), so for a beam incident perpendicular to such a diffraction grating, output with minimal energy loss is obtained, and for a beam incident at an angle, in the case of a planar diffraction grating, the losses will be large. If bulk Bragg gratings are used, then the efficiency of the passage of radiation incident at an angle through the expander can be increased.

The main advantage of using a curved waveguide is that an expander with such a waveguide can be embedded in visual systems with a very large angular field at the output. There is a limit on the angles of incidence on a flat expander, if the angular field of the visual system exceeds the angular working limit of the expander, the exit pupil will not be correctly multiplied. Thus, when using a planar waveguide, any type of diffraction grating can be used, then the system for expanding the area of the exit pupil can be used for systems with a small field of view; and when using a curved waveguide, Bragg diffraction gratings can be used, then the exit pupil expansion system can be used for wide-field systems.

The present invention can find wide applications in optical devices as a compact and convenient additional element that expands the area of the exit pupil of optical devices.

Although the invention has been described in connection with some illustrative embodiments, it should be understood that the invention is not limited to these specific embodiments. On the contrary, it is assumed that the invention includes all alternatives, corrections and equivalents that may be included in the essence and scope of the claims.

In addition, the invention retains all equivalents of the claimed invention, even if the claims change during the review process.

Claims (35)

1. A system for expanding the area of the exit pupil of the visual optical system, comprising: waveguide; a diffraction grating located on the surface of the waveguide; moreover, the parameters of the diffraction grating are consistent with the parameters of the waveguide in such a way that: the diffraction grating is configured to: - the formation, due to the diffraction of each of the radiation beams incident on the diffraction grating from the visual optical system, of at least two diffraction orders, and - dividing each of the radiation beams returning to the diffraction grating due to total internal reflection from the surface of the waveguide opposite the diffraction grating into at least two radiation beams; the waveguide is configured to: - exit from the side of the surface of the waveguide opposite the diffraction grating, each of the at least two diffraction orders from the diffraction grating and at least two radiation beams from the diffraction grating with the formation of exit pupil units forming a set of multiplied rays in the area of the output pupil of the visual optical systems; - return of the remaining radiation beams due to total internal reflection from the waveguide surface opposite the diffraction grating to the diffraction grating. 2. The system of claim 1, wherein the visual optical system is an augmented reality device. 3. The system according to claim 1, in which the visual optical system is one of the devices, which are: a microscope, telescope, sight, augmented reality device, a device in which the image is formed at infinity. 4. The system of claim 1, wherein the diffraction grating is reflective. 5. The system of claim 1, wherein the diffraction grating is transmission. 6. The system according to any one of paragraphs. 1-3, in which the diffraction grating is a diffractive optical element. 7. The system according to any one of paragraphs. 1-3, in which the diffraction grating is a holographic optical element. 8. The system of claim 1, wherein the diffraction grating is one-dimensional. 9. The system of claim 1, wherein the diffraction grating is two-dimensional. 10. The system of claim 1, wherein the waveguide has a curved shape. 11. The system of claim 1, wherein the diffraction grating is a Bragg grating. 12. A visual optical system comprising a system for expanding the area of the exit pupil according to any one of paragraphs. 1–11. 13. The visual optical system according to claim 12, in which the system for expanding the area of the exit pupil is located at the output of the visual optical system. 14. The visual optical system according to any one of paragraphs. 12, 13, in which the visual optical system emits multispectral radiation. 15. The visual optical system according to any one of paragraphs. 12, 13, in which the visual optical system emits monospectral radiation. 16. The visual optical system according to claim 12, in which the system for expanding the area of the exit pupil works in the lumen. 17. The visual optical system according to claim 12, in which the system of expanding the area of the exit pupil works on reflection. 18. The method of operation of the system to expand the area of the exit pupil according to any one of paragraphs. 1-11, containing stages in which: - feed the radiation beams from the visual optical system to the expansion system of the exit pupil area; - form due to the diffraction of each of the radiation beams incident on the diffraction grating from the visual optical system, at least two diffraction orders so that: one of the at least two diffraction orders mentioned extends from the side of the waveguide surface opposite to the diffraction grating and forms a unit of the exit pupil of the visual optical system; while the remaining radiation beams: undergo complete internal reflection from the surface of the waveguide, opposite the diffraction grating, and return to the diffraction grating, each of the radiation beams returning to the diffraction grating is separated by the diffraction grating into at least two radiation beams, one of which extends from the side of the waveguide surface opposite to the diffraction grating, forming a unit of the exit pupil of the visual optical system; moreover, the formed units of the exit pupil of the visual optical system form a set of multiplied rays in the area of the exit pupil of the visual optical system.

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