CN107203040A - The processing method of head-wearing display device and its eyepiece optical system - Google Patents

Abstract

The present invention relates to the processing method of head-wearing display device and its eyepiece optical system, including the eyepiece optical system and display screen being correspondingly arranged；The corresponding length of the effective display picture of display screen is with width ratio scope：1:1-16:3, eyepiece optical system includes one or more lens；The broadside of the lens of at least one in eyepiece optical system is to carry out the broadside after trimming processing, and the reservation size minimum value and the maximum effectively optical aperture ratio range of lens after lens broadside trimming are：0.22-0.66.The present invention program carries out trimming by the broadside to lens, the length for retaining its long side is constant, so that eyepiece optical system overall weight mitigates, and easy processing and assembling, simultaneously eyepiece optical system can be ensured in the case where meeting the optical properties such as the big angle of visual field, hi-vision resolving power, low distortion, the small curvature of field, small size so that head-wearing display device product is worn more comfortable.

Description

Head-mounted display device and processing method of eyepiece optical system thereof

Technical Field

The invention relates to the technical field of optics, in particular to a head-mounted display device and a processing method of an eyepiece optical system of the head-mounted display device.

Background

With the continuous development of electronic devices towards ultra-miniaturization and the development of new computer, micro-electronics, photoelectric devices and communication theory and technology, the novel mode based on human-oriented and man-machine-in-one of wearable computing becomes possible. The method is continuously applied to the fields of military affairs, industry, medical treatment, education, consumption and the like. In a typical wearable computing system architecture, the head mounted display device is a key component. The head-mounted display device guides video image light emitted by a miniature image display (such as a transmission type or reflection type liquid crystal display, an organic electroluminescent device and a DMD device) to pupils of a user through an optical technology, realizes virtual and enlarged images in the near-eye range of the user, and provides visual and visible images, videos and character information for the user. The eyepiece optical system is the core of the head-mounted display device and realizes the function of displaying the miniature image in front of human eyes to form a virtual amplified image.

The head-mounted display device is developed in the directions of compact size, light weight, convenience in head mounting, load reduction and the like. Meanwhile, the large field angle and the visual comfort experience gradually become key factors for measuring the quality of the head-mounted display device, the large field angle determines the visual experience effect with high telepresence, and the high image quality and low distortion determine the comfort level of the visual experience. Meeting these requirements requires that the eyepiece optical system achieve as large an angle of view, high image resolution, low distortion, small curvature of field, small volume, etc., as possible, and meeting the above optical performance is a great challenge to the design and aberration optimization of the system.

When processing eyepiece optical system, generally need carry out the side cut processing to eyepiece optical system according to the size of display screen size, still can guarantee satisfying under the circumstances of above-mentioned optical property, lighten eyepiece optical system's weight and volume as far as possible for wear display device product and wear more comfortablely.

Disclosure of Invention

The present invention is directed to provide a head-mounted display device of a wide-band edge-cut eyepiece optical system with good optical performance, compact size, light weight, and good processability.

The technical scheme adopted by the invention for solving the technical problems is as follows:

constructing a head-mounted display device, which comprises an eyepiece optical system and a display screen which are correspondingly arranged; the length and width ratio range corresponding to the effective display picture of the display screen is as follows: 1:1-16:3, wherein the eyepiece optical system at least comprises one or more lenses; the wide side of at least one lens is the wide side subjected to trimming treatment, and the ratio range of the minimum value of the reserved size of the trimmed wide side of the lens to the maximum effective optical aperture of the lens is as follows: 0.22-0.66.

The head-mounted display device comprises a lens, a lens holder, a lens driving device and a lens driving device, wherein the long edge of at least one lens is a long edge subjected to edge cutting, and the front view of the lens subjected to the long edge cutting is a rectangle with four arc-shaped corners;

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is 1.03-1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after edge cutting to the maximum effective optical aperture of the lens is as follows: greater than 0.80.

The head-mounted display device comprises a lens, a lens holder, a lens driving device and a lens driving device, wherein the long edge of at least one lens is a long edge subjected to edge cutting, and the front view of the lens subjected to the long edge cutting is a rectangle with four arc-shaped corners;

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is greater than 1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after being cut to the maximum effective optical aperture of the lens is as follows: greater than 0.9.

The head-mounted display device provided by the invention has the advantages that the length-width ratio corresponding to the effective display picture of the display screen is 16:16, the ratio range of the minimum value of the reserved size of the lens after the broadside edge trimming to the maximum effective optical aperture of the lens is as follows: greater than 0.66;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.80.

The head-mounted display device provided by the invention has the advantages that the length-width ratio corresponding to the effective display picture of the display screen is 16:12, and the ratio of the minimum reserved size of the trimmed broadsides of the lenses to the maximum effective optical aperture of the lenses is as follows: greater than 0.57;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.87.

The head-mounted display device provided by the invention has the advantages that the length-width ratio corresponding to the effective display picture of the display screen is 16:10, the ratio range of the minimum value of the reserved size of the lens after the broadside edge trimming to the maximum effective optical aperture of the lens is as follows: greater than 0.51;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.91.

The head-mounted display device provided by the invention is characterized in that the length-width ratio corresponding to the effective display picture of the display screen is 16:9, and the ratio range of the minimum value of the reserved size of the lens after the broadside edge trimming to the maximum effective optical aperture of the lens is as follows: greater than 0.47;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.93.

The head-mounted display device of the present invention, wherein the eyepiece optical system comprises two lenses, each of which is: a first lens and a second lens; wherein,

the wide edge of the first lens is subjected to over-cutting edge treatment;

the wide side of the second lens is the wide side subjected to edge cutting, and the long side of the second lens is the long side subjected to edge cutting.

The head-mounted display device of the present invention, wherein the eyepiece optical system includes three lenses, each of which is: a first lens, a second lens, and a third lens; wherein,

the wide sides of the first lens, the second lens and the third lens are the wide sides subjected to edge cutting treatment, and the long sides of the first lens, the second lens and the third lens are the long sides subjected to edge cutting treatment.

The head-mounted display device of the present invention, wherein the eyepiece optical system includes four lenses, each of which is: a fourth lens, a fifth lens, a sixth lens, and a seventh lens; wherein,

the wide sides of the fourth lens, the fifth lens, the sixth lens and the seventh lens are all subjected to edge cutting treatment.

The invention provides a head-mounted display device, wherein the head-mounted display device is a monocular head-mounted display device, comprising:

an eyepiece optical system; and a display screen corresponding to the eyepiece optical system.

The invention provides a head-mounted display device, wherein the head-mounted display device is a binocular head-mounted display device, comprising:

a left eye eyepiece optical system; and a left eye display screen corresponding to the left eye eyepiece optical system;

a right eye eyepiece optical system; and a right eye display screen corresponding to the right eye eyepiece optical system.

The head-mounted display device of the present invention, wherein the eyepiece optical system includes:

the lens comprises a first lens, a second lens and a third lens which are coaxially and sequentially arranged along the direction of an optical axis, wherein the first lens is close to the side of human eyes, the third lens is close to the side of an image source, and light rays of the image source are watched by the human eyes through the third lens, the second lens and the first lens in sequence;

the combined focal power formed by the first lens and the second lens is a positive value, and the surface of the second lens close to the image source side is convex to the image source direction;

the curvature directions of the two optical surfaces of the third lens are the same and are both concave to the direction of the image source.

The head-mounted display device of the present invention, wherein the eyepiece optical system includes:

the lens comprises a first lens group and a second lens group which are coaxially and sequentially arranged along the direction of an optical axis from the observation side of human eyes to the display screen side, wherein the effective focal length of the first lens group is a negative value, and the effective focal length of the second lens group is a positive value;

the first lens group consists of two lenses, namely a fourth lens close to the human eye side and a fifth lens far away from the human eye side, the fourth lens is a biconvex positive lens, and the fourth lens is a negative lens; the optical surface of the fifth lens close to the human eye side is concave to the human eye side, and the curvature radius is a negative value;

the second lens group is composed of one or more lenses, wherein the second lens group at least comprises a sixth lens adjacent to the first lens group and a seventh lens, the sixth lens is a positive lens, and the seventh lens is positioned between the sixth lens and the display screen side.

The head-mounted display device of the present invention, wherein the eyepiece optical system includes: the lens comprises a first lens group and a second lens group which are coaxially and sequentially arranged along the direction of an optical axis from the observation side of human eyes to the display screen side, wherein the effective focal length of the first lens group is a negative value, and the effective focal length of the second lens group is a positive value;

the first lens group consists of two lenses, namely an eighth lens close to the human eye side and a ninth lens far away from the human eye side, the eighth lens is a biconvex positive lens, and the ninth lens is a negative lens; the second lens group is composed of one or more lenses, wherein the second lens group at least comprises a tenth lens adjacent to the first lens group, and the tenth lens is a positive lens;

the second lens group further comprises an eleventh lens and a twelfth lens, and the tenth lens, the eleventh lens and the twelfth lens are arranged in sequence from the human eye side to the micro display side;

the eleventh lens is located between the tenth lens and the display screen side.

The invention also provides a processing method of the eyepiece optical system of the head-mounted display device, which comprises the following steps:

trimming the wide edge of the lens of the head-mounted display device;

wherein the ratio range of the minimum value of the reserved size of the lens after the broadside edge trimming and the maximum effective optical aperture of the lens is as follows: 0.22-0.66; the length and width ratio range corresponding to the effective display picture of the display screen is as follows: 1:1-16:3.

The processing method comprises the following steps that the reserved size of the lens after the broadside edge cutting is D, the reserved size of the lens after the long side edge cutting is E, and the outer diameter of the eyepiece optical system before processing is B; wherein B, D, E satisfies the following relation (3):

(3)；

and when the value of E/B is more than 0.92, the long-edge trimming processing is not carried out on the eyepiece optical system.

The processing method of the invention further comprises the following steps: performing edge cutting processing on the long edge of the lens of the head-mounted display device; wherein,

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is 1.03-1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after edge cutting to the maximum effective optical aperture of the lens is as follows: greater than 0.80;

or further comprising the steps of: performing edge cutting processing on the long edge of the lens of the head-mounted display device; wherein,

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is greater than 1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after being cut to the maximum effective optical aperture of the lens is as follows: greater than 0.9.

The invention has the beneficial effects that: the wide edge of the lens is trimmed or the long edge of the lens is trimmed simultaneously according to a set cutting method, so that the whole weight of the eyepiece optical system is reduced, the eyepiece optical system is easy to process and assemble, and meanwhile, the eyepiece optical system can be ensured to be more comfortable to wear under the condition of meeting optical performances such as a large field angle, high image resolution, low distortion, small curvature of field, small volume and the like.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the present invention will be further described with reference to the accompanying drawings and embodiments, wherein the drawings in the following description are only part of the embodiments of the present invention, and for those skilled in the art, other drawings can be obtained without inventive efforts according to the accompanying drawings:

FIG. 1 is a schematic view of a wide edge trimming method of a head-mounted display device according to a preferred embodiment of the invention;

FIG. 2 is a front view of the eyepiece optics after being broadside trimmed for a head mounted display device in accordance with a preferred embodiment of the present invention;

FIG. 3 is a schematic perspective view of a wide-edged eyepiece optical system of a head-mounted display device according to a preferred embodiment of the present invention;

FIG. 4 is a schematic optical path diagram of an eyepiece optical system of a head mounted display device before being broadside trimmed according to a preferred embodiment of the present invention;

FIG. 5 is a schematic diagram of the optical path of the eyepiece optics after broadside trimming for a head-mounted display device according to a preferred embodiment of the present invention;

FIG. 6 is a first schematic view illustrating a manner of trimming the wide side and the long side of the head-mounted display device according to the preferred embodiment of the invention;

FIG. 7 is a first view of the front structure of the eyepiece optics system after both the wide side and the long side of the head mounted display device are trimmed simultaneously in accordance with the preferred embodiment of the present invention;

FIG. 8 is a first perspective view of the eyepiece optics system of the head mounted display device of the preferred embodiment of the present invention after both the wide side and the long side have been trimmed;

FIG. 9 is a schematic optical path diagram of the eyepiece optics system shown in FIGS. 7 and 8;

FIG. 10 is a schematic diagram illustrating a second embodiment of a method for trimming a wide side and a long side of a head-mounted display device according to the present invention;

FIG. 11 is a second front view of the eyepiece optics system of the head mounted display device of the preferred embodiment of the present invention after both the wide and long sides have been trimmed;

FIG. 12 is a second perspective view of the eyepiece optics system after both broadside and long side trimming in accordance with the preferred embodiment of the present invention;

FIG. 13 is a schematic diagram of the optical path of the eyepiece optics before simultaneous trimming of the wide and long sides in accordance with a preferred embodiment of the present invention;

FIG. 14 is a schematic diagram of the optical path of the eyepiece optics after both the wide and long sides have been trimmed in accordance with a preferred embodiment of the present invention;

fig. 15 is a schematic view illustrating a lens chamfering process performed by the head-mounted display device according to the preferred embodiment of the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following will clearly and completely describe the technical solutions in the embodiments of the present invention, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without inventive step, are within the scope of the present invention.

The head-mounted display device of the bandwidth edge-trimming eyepiece optical system comprises an eyepiece optical system and a display screen which are correspondingly arranged; the length and width ratio range corresponding to the effective display picture of the display screen is as follows: 1:1-16: 3; the eyepiece optical system includes at least one or more lenses; wherein, the broadside that has a piece lens at least is for carrying on the broadside after the side cut is handled, and the biggest effective optical aperture ratio range of size minimum and lens of remaining after the side cut of lens broadside is: 0.22-0.66, comprising: 0.22, 0.27, 0.32, 0.36, 0.40, 0.44, 0.47, 0.51, 0.54, 0.57, 0.59, 0.62, 0.64, 0.66. Or further, the ratio range of the length and the width corresponding to the effective display picture of the display screen is as follows: 1:1-2: 1; the eyepiece optical system includes at least one or more lenses; wherein, the broadside that has a piece lens at least is for carrying on the broadside after the side cut is handled, and the biggest effective optical aperture ratio range of size minimum and lens of remaining after the side cut of lens broadside is: 0.44-0.66.

After the wide edge of the lens is subjected to edge cutting, the ratio range of the minimum reserved size and the maximum effective optical aperture of the lens is as follows: 0.22-0.66, preferably 0.44-0.66, not only can make the whole weight of the eyepiece optical system lightened, easy to process and assemble, but also can ensure that the eyepiece optical system meets the optical performances of large field angle, high image resolution, low distortion, small curvature of field, small volume and the like, and makes the head-mounted display device more comfortable to wear.

Because the eyepiece optical system is an axisymmetric optical structure, when the eyepiece optical system is used for observing a rectangular display area, a part of light passing range is not effectively utilized, so that the long side and/or the wide side of the lens can be cut according to the effective display picture proportion of the display screen, the optical structure part corresponding to the light passing range which is not effectively utilized is removed, and the optical structure of the rest part can still ensure that the requirements for optical performances such as a large field angle, high image resolution, low distortion, small curvature of field, small volume and the like are met.

Fig. 1 shows a broadside trimming method of a head-mounted display device, wherein two parallel dotted line positions are cutting lines, a solid circular ring with a larger diameter represents the original size of the lens, and a solid circular ring with a smaller diameter represents the maximum effective optical size of the lens. Wherein, A is the maximum effective optical aperture of the lens, B is the outer diameter of the lens, C is the processing and manufacturing allowance of the lens, and D is the reserved size of the lens after the broadside edge is cut.

Fig. 2 shows a front structure of the eyepiece optical system after trimming by using the trimming method of fig. 1, and fig. 3 shows a three-dimensional assembly structure of the eyepiece optical system after trimming by using the trimming method of fig. 1, in which the upper and lower edges are cut off, and arcs on both sides are retained, thereby facilitating the installation and fixation of the eyepiece optical system in the head-mounted display device. FIG. 4 is a schematic view of the optical path of the eyepiece optics before being broadside trimmed, showing that the light coverage does not involve the entire surface of the eyepiece optics, but rather a rectangular area thereof; fig. 5 shows a schematic diagram of an optical path of the eyepiece optical system after being trimmed by a wide edge, and it can be seen that a part of the lens is cut off and the light passing part of the lens is not affected, so that the eyepiece optical system is ensured to meet optical performances such as a large field angle, high image resolution, low distortion, small curvature of field, small volume and the like.

In a further embodiment, the long side of at least one lens in the eyepiece optical system of the head-mounted display device is a long side subjected to trimming, and a front view of the lens subjected to trimming of the long side is a rectangle with four arc-shaped corners; when the ratio of the outer diameter of the lens to the maximum effective optical aperture is 1.03-1.1, the minimum value of the reserved size after the long edge of the lens is cut off and the ratio range of the maximum effective optical aperture of the lens are as follows: greater than 0.80; or when the ratio of the outer diameter of the lens to the maximum effective optical aperture is greater than 1.1, the minimum value of the reserved size after the long edge of the lens is cut off and the ratio range of the maximum effective optical aperture of the lens is as follows: greater than 0.9.

Fig. 6 shows a way of trimming the long side and the wide side of the head-mounted display device at the same time, wherein two sets of parallel dotted lines are respectively the long side and the wide side trimming lines, the solid line ring with larger diameter represents the original size of the lens, and the solid line ring with smaller diameter represents the maximum effective optical size of the lens. Wherein, A is the maximum effective optical aperture of the lens, B is the outer diameter of the lens, C is the processing and manufacturing allowance of the lens, D is the reserved size of the lens after the broadside edge cutting, and E represents the reserved size of the lens after the long side edge cutting.

Fig. 7 and 8 show the front structure and the three-dimensional structure of the eyepiece optical system of the head-mounted display device of the present invention after performing simultaneous trimming of the wide side and the long side in the manner illustrated in fig. 6, respectively, and it can be seen that the lens after performing trimming of the wide side and the long side is a rectangle with four arc-shaped corners. Fig. 9 shows a quarter of the optical path diagram of the eyepiece optical system in fig. 7 and 8, and it can be seen that even if long-side and wide-side trimming is performed, the optical path 100 is not affected, and the eyepiece optical system can still meet the optical performance of large field angle, high image resolution, low distortion, small curvature of field, small volume, and the like.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:16, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.66; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.80.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:15, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.64; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.82.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:14, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.62; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.84.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:13, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.59; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.86.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:12, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is: greater than 0.57; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.87.

Preferably, in the head-mounted display device, the length-to-width ratio range corresponding to the effective display screen on the display screen is: when the ratio of the minimum value of the reserved size of the lens after the broadside edge cutting to the maximum effective optical aperture of the lens is more than 16: 11: greater than 0.54; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.89.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:10, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.51; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.91.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:9, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.47; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.93.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:8, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.44; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.94.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:7, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.40; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.96.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:6, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.36; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.98.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:5, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.32; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.99.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:4, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.27; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 1.00.

Preferably, in the head-mounted display device, when the length-to-width ratio corresponding to the effective display frame of the display screen is 16:3, the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in a range of: greater than 0.22; and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 1.02.

Fig. 10 shows a way of trimming the long side and the wide side of the head-mounted display device at the same time, wherein two sets of parallel dotted lines are respectively the long side and the wide side trimming lines, the solid line ring with larger diameter represents the original size of the lens, and the solid line ring with smaller diameter represents the maximum effective optical size of the lens. Wherein, A is the maximum effective optical aperture of the lens, B is the outer diameter of the lens, C is the processing and manufacturing allowance of the lens, D is the reserved size of the lens after the broadside edge cutting, and E represents the reserved size of the lens after the long side edge cutting.

Fig. 11 and 12 show the front structure and the three-dimensional structure of the eyepiece optical system of the head-mounted display device of the present invention after performing simultaneous trimming of the wide side and the long side in the manner illustrated in fig. 10, respectively, and it can be seen that the lens 30 after performing the trimming of the wide side and the long side is rectangular; the ratio range of the minimum value of the reserved size after the long edge of the lens is cut and the maximum effective optical aperture of the lens is as follows: 0.683-0.992. Fig. 13 shows the optical path diagram of the eyepiece optical system before the long-side and wide-side trimming is performed in the manner of fig. 6 and 10, and fig. 14 shows the optical path diagram of the eyepiece optical system after the long-side and wide-side trimming is performed in the manner of fig. 6 and 10, so that even if the long-side and wide-side trimming is performed, the optical path 100 is not affected, and the eyepiece optical system can still meet the optical performance requirements of large field angle, high image resolution, low distortion, small curvature of field, small volume and the like.

Preferably, in the above embodiment, the trimming process is performed in the manner illustrated in fig. 10, and when the ratio of the length to the width corresponding to the effective display frame of the display screen is 16:16, the ratio range of the minimum value of the reserved size after the broadside of the lens is trimmed to the maximum effective optical aperture of the lens is: greater than 0.66; the ratio range of the minimum value of the reserved size after the long edge of the lens is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.683;

preferably, in the above embodiment, the trimming process is performed in the manner illustrated in fig. 10, and when the ratio of the length to the width corresponding to the effective display frame of the display screen is 16:12, the ratio of the minimum reserved size after the broadside of the lens is trimmed to the maximum effective optical aperture of the lens is: greater than 0.57; the ratio range of the minimum value of the reserved size after the long edge of the lens is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.778.

Preferably, in the above embodiment, the trimming process is performed in the manner illustrated in fig. 10, and when the ratio of the length to the width corresponding to the effective display frame of the display screen is 16:10, the ratio range of the minimum value of the reserved size after the broadside of the lens is trimmed to the maximum effective optical aperture of the lens is: greater than 0.51; the ratio range of the minimum value of the reserved size after the long edge of the lens is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.832.

Preferably, in the above embodiment, the trimming process is performed in the manner illustrated in fig. 10, and when the ratio of the length to the width corresponding to the effective display frame of the display screen is 16:9, the ratio range of the minimum value of the reserved size after the broadside of the lens is trimmed to the maximum effective optical aperture of the lens is: greater than 0.47; the ratio range of the minimum value of the reserved size after the long edge of the lens is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.860.

In a further embodiment, the edge-cutting process is performed in the manner illustrated in fig. 15, the long side of the lens is the long side subjected to the edge-cutting process, and the front view of the lens is a polygon formed by cutting four corners of a rectangle; the parts of the front view of the lens, the four corners of which are cut off, are all triangular; the side length of a side z1 corresponding to the wide side of the triangle and the wide side of the lens is recorded as F, the side length of a side z2 corresponding to the long side of the triangle and the long side of the lens is recorded as G, the side length of a third side z3 of the triangle is recorded as H, an angle corresponding to z1 to z3 is ═ alpha, and an angle from a diagonal line of an effective display picture of the display screen to the long side of the effective picture of the display screen is ═ beta; wherein the following relational expressions (1) and (2) are satisfied:

∠α＝∠β＝atan(b/a) (1)；

F/D≤0.26 (2)；

in the above relations (1) and (2), a is the length corresponding to the effective display frame of the display screen, b is the width corresponding to the effective display frame of the display screen, and D is the reserved size of the lens after the wide edge is trimmed.

In each embodiment provided by the present invention, the head-mounted display device may be a monocular head-mounted display device, including: an eyepiece optical system; and a display screen corresponding to the eyepiece optical system. Or, the head-mounted display device is a binocular head-mounted display device, including: a left eye eyepiece optical system; and a left eye display screen corresponding to the left eye eyepiece optical system; a right eye eyepiece optical system; and a right eye display screen corresponding to the right eye eyepiece optical system.

In a specific embodiment, as shown in fig. 7, 8 and 9, the eyepiece optical system of the head-mounted display device includes two lenses 20: a first lens 21 and a second lens 22. Wherein the wide side of the first lens 21 is the wide side subjected to the over-cutting treatment; the wide side of the second lens 22 is a wide side subjected to the edge-cutting process, and the long sides of the first lens 21 and the second lens 22 are long sides subjected to the edge-cutting process. The ratio of the minimum value of the remaining size after the broadside trimming of the first lens 21 and the second lens 22 to the maximum effective optical aperture of the lenses is in the range: 0.22-0.66. When the ratio of the outer diameter of the lens to the maximum effective optical aperture is 1.03-1.1, the minimum value of the reserved size after the long edge of the lens is cut off and the ratio range of the maximum effective optical aperture of the lens are as follows: greater than 0.80. When the ratio of the outer diameter of the lens to the maximum effective optical aperture is greater than 1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after cutting edge to the maximum effective optical aperture of the lens is as follows: greater than 0.9.

In another specific embodiment, as shown in fig. 13 and 14, the eyepiece optical system of the head-mounted display device includes three lenses: the optical lens comprises a first lens 21, a second lens 22 and a third lens 23 which are coaxially and sequentially arranged along the optical axis direction, wherein the first lens 21 is close to the human eye side, the third lens 23 is close to the image source side, and the image source light rays are watched by the human eye through the third lens 23, the second lens 22 and the first lens 21 in sequence; the surface of the second lens 22 close to the image source side is convex to the image source direction; the curvature directions of the two optical surfaces of the third lens 23 are the same, and both are concave to the image source direction.

Preferably, the wide sides of the first lens 21, the second lens 22 and the third lens 23 are wide sides subjected to edge trimming, and the ratio of the minimum value of the reserved size of the wide sides subjected to edge trimming to the maximum effective optical aperture of the lenses is in the range: 0.22-0.66, more preferably: 0.44-0.66; meanwhile, the long sides of the first lens 21, the second lens 22 and the third lens 23 are long sides subjected to edge cutting; and the ratio range of the minimum value of the reserved size after the long sides of the second lens 22 and the third lens 23 are cut and the maximum effective optical aperture ratio of the second lens 22 and the third lens 23 is as follows: greater than 0.8, the minimum value of the remaining size after the long edge trimming of the first lens 21 and the maximum effective optical aperture ratio range of the second lens 22 and the third lens 23 are as follows: 0.683-0.992.

In another specific embodiment, as shown in fig. 2, 3, 4, and 5, the eyepiece optical system of the head-mounted display device includes four lenses 10: the lens comprises a first lens group and a second lens group which are coaxially and sequentially arranged along the direction of an optical axis from the observation side of human eyes to the display screen side, wherein the effective focal length of the first lens group is a negative value, and the effective focal length of the second lens group is a positive value; the first lens group is composed of two lenses, namely a fourth lens 11 close to the human eye side and a fifth lens 12 far away from the human eye side, the fourth lens 11 is a biconvex positive lens, and the fourth lens 11 is a negative lens; the optical surface of the fifth lens 12 close to the human eye side is concave to the human eye side, and the curvature radius is a negative value; the second lens group is composed of one or more lenses, wherein the second lens group at least comprises a sixth lens 13 adjacent to the first lens group and a seventh lens 14, the sixth lens 13 is a positive lens, and the seventh lens 14 is located between the sixth lens 13 and the display screen side.

Preferably, the wide sides of the fourth lens 11, the fifth lens 12, the sixth lens 13 and the seventh lens 14 are all subjected to edge cutting; and the ratio range of the minimum value of the reserved size of the lens after the broadside edge cutting and the maximum effective optical aperture of the lens is as follows: 0.22-0.66.

In another specific embodiment, the eyepiece optical system of the head mounted display device includes five lenses (not shown): the lens comprises a first lens group and a second lens group which are coaxially and sequentially arranged along the direction of an optical axis from the observation side of human eyes to the display screen side, wherein the effective focal length of the first lens group is a negative value, and the effective focal length of the second lens group is a positive value; the first lens group consists of two lenses, namely an eighth lens close to the human eye side and a ninth lens far away from the human eye side, the eighth lens is a biconvex positive lens, and the ninth lens is a negative lens; the optical surface of the ninth lens close to the human eye side is concave to the human eye side, and the curvature radius is a negative value; the second lens group is composed of one or more lenses, wherein the second lens group at least comprises a tenth lens adjacent to the first lens group, and the tenth lens is a positive lens; the second lens group further comprises an eleventh lens and a twelfth lens, and the tenth lens, the eleventh lens and the twelfth lens are arranged in sequence from the human eye side to the micro display side; the eleventh lens is located between the tenth lens and the display screen side. The eighth lens element, the ninth lens element, the tenth lens element, the eleventh lens element, and the twelfth lens element are subjected to the broadside trimming or both the broadside trimming and the long-side trimming in the same manner as in the foregoing embodiments.

In another embodiment of the present invention, there is also provided a method for manufacturing an eyepiece optical system of a head-mounted display device, referring to fig. 1, including the steps of: trimming the wide edge of the lens of the head-mounted display device; wherein, the ratio range of the minimum value of the reserved size after the broadside edge cutting of the lens and the maximum effective optical aperture of the lens is as follows: 0.22-0.66; the length and width ratio range corresponding to the effective display picture of the display screen is as follows: 1:1-16:3. After the wide edge of the lens is subjected to edge cutting, the ratio range of the minimum reserved size and the maximum effective optical aperture of the lens is as follows: 0.22-0.66, not only the whole weight of the ocular optical system is reduced, and the ocular optical system is easy to process and assemble, but also the ocular optical system can meet the optical performances of large field angle, high image resolution, low distortion, small curvature of field, small volume and the like, so that the head-mounted display device is more comfortable to wear.

In the processing method, the reserved size of the lens after the broadside edge cutting is D, the reserved size of the lens after the long side edge cutting is E, and the outer diameter of the eyepiece optical system before processing is B; wherein B, D, E satisfies the following relation (3):

(3)；

when the value of E/B is more than 0.92, the long-edge trimming processing is not performed on the eyepiece optical system.

Referring to fig. 6, when the value of E/B is less than or equal to 0.92, the processing method further includes the steps of: performing edge cutting processing on the long edge of the lens of the head-mounted display device; wherein, when the ratio of the outer diameter of the lens to the maximum effective optical aperture is 1.03-1.1, the minimum value of the reserved size after the long edge of the lens is cut edge and the range of the ratio of the maximum effective optical aperture of the lens is as follows: greater than 0.80.

Referring to fig. 6, when the value of E/B is less than or equal to 0.92, the processing method further includes the steps of: performing edge cutting processing on the long edge of the lens of the head-mounted display device; wherein, when lens external diameter and the biggest effective optical aperture ratio are for being greater than 1.1, the size minimum that remains after the long limit side cut of lens and the biggest effective optical aperture ratio scope of lens are: greater than 0.9.

Referring to fig. 10, the processing method further includes the steps of: performing edge cutting processing on the long edge of the lens of the head-mounted display device; wherein the front view of the lens is rectangular; the ratio range of the minimum value of the reserved size after the long edge of the lens is cut and the maximum effective optical aperture of the lens is as follows: 0.683-0.992.

Referring to fig. 15, the above processing method further includes the steps of: carrying out corner cutting treatment on the lens, wherein the front view of the lens is a polygon formed by cutting four corners of a rectangle; the parts of the front view of the lens, the four corners of which are cut off, are all triangular; the side length of a side z1 corresponding to the wide side of the triangle and the wide side of the lens is recorded as F, the side corresponding to the long side of the triangle and the long side of the lens is recorded as z2, the third side of the triangle is recorded as z3, the angle corresponding to z1 to z3 is ^ α, and the angle from the diagonal of the effective display picture of the display screen to the long side of the effective display picture of the display screen is ^ β;

wherein the following relational expressions (1) and (2) are satisfied:

∠α＝∠β＝atan(b/a) (1)；

F/D≤0.26 (2)；

in the above relations (1) and (2), a is the length corresponding to the effective display frame of the display screen, b is the width corresponding to the effective display frame of the display screen, and D is the reserved size of the lens after the wide edge is trimmed.

In conclusion, the invention cuts the edge of the wide edge of the lens or cuts the edge of the long edge of the lens according to the set cutting method, so that the whole weight of the eyepiece optical system is reduced, the eyepiece optical system is easy to process and assemble, and the eyepiece optical system can be ensured to be more comfortable to wear under the condition of meeting the optical performances of large field angle, high image resolution, low distortion, small curvature of field, small volume and the like.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (18)

1. A head-mounted display device comprises an eyepiece optical system and a display screen which are correspondingly arranged; the length and width ratio range corresponding to the effective display picture of the display screen is as follows: 1:1-16:3, wherein the eyepiece optical system at least comprises one or more lenses; the method is characterized in that at least one wide edge of the lens is a wide edge subjected to trimming treatment, and the ratio range of the minimum value of the reserved size of the trimmed wide edge of the lens to the maximum effective optical aperture of the lens is as follows: 0.22-0.66.

2. The head-mounted display device according to claim 1, wherein the long side of at least one of the lenses is a long side subjected to trimming, and a front view of the lens subjected to the trimming of the long side is a rectangle having four corners in a circular arc shape;

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is 1.03-1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after edge cutting to the maximum effective optical aperture of the lens is as follows: greater than 0.80.

3. The head-mounted display device according to claim 1, wherein the long side of at least one of the lenses is a long side subjected to trimming, and a front view of the lens subjected to the trimming of the long side is a rectangle having four corners in a circular arc shape;

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is greater than 1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after being cut to the maximum effective optical aperture of the lens is as follows: greater than 0.9.

4. The head-mounted display device of claim 1, 2 or 3, wherein the ratio of the length to the width of the effective display frame of the display screen is 16:16, and the ratio of the minimum value of the reserved size of the lens after the broadside trimming to the maximum effective optical aperture of the lens is in the range: greater than 0.66;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.80.

5. The head-mounted display device of claim 1, 2 or 3, wherein the ratio of the length to the width of the effective display frame of the display screen is 16:12, and the ratio of the minimum reserved size of the lens after the broadside trimming to the maximum effective optical aperture of the lens is: greater than 0.57;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.87.

6. The head-mounted display device of claim 1, 2 or 3, wherein the ratio of the length to the width of the effective display frame of the display screen is 16:10, and the ratio of the minimum value of the reserved size of the lens after the broadside trimming to the maximum effective optical aperture of the lens is in the range: greater than 0.51;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.91.

7. The head-mounted display device of claim 1, 2 or 3, wherein the ratio of the length to the width of the effective display frame of the display screen is 16:9, and the ratio of the minimum reserved size after the broadside trimming of the lens to the maximum effective optical aperture of the lens is in the range: greater than 0.47;

and/or the ratio range of the minimum value of the reserved size of the lens after the long edge is cut and the maximum effective optical aperture of the lens is as follows: greater than 0.93.

8. A head-mounted display device as claimed in claim 1, 2 or 3, wherein the eyepiece optical system comprises two lenses, respectively: a first lens and a second lens; wherein,

the wide edge of the first lens is subjected to over-cutting edge treatment;

the wide side of the second lens is the wide side subjected to edge cutting, or the long side of the second lens is the long side subjected to edge cutting.

9. A head-mounted display device as claimed in claim 1, 2 or 3, wherein the eyepiece optical system comprises three lenses, respectively: a first lens, a second lens, and a third lens; wherein,

the wide sides of the first lens, the second lens and the third lens are the wide sides subjected to edge cutting treatment, or the long sides of the first lens, the second lens and the third lens are the long sides subjected to edge cutting treatment.

10. The head-mounted display device according to claim 1, wherein the eyepiece optical system includes four lenses, each of which is: a fourth lens, a fifth lens, a sixth lens, and a seventh lens; wherein,

the wide sides of the fourth lens, the fifth lens, the sixth lens and the seventh lens are all subjected to edge cutting treatment.

11. The head mounted display device of claim 1, 2 or 3, wherein the head mounted display device is a monocular head mounted display device comprising:

an eyepiece optical system; and a display screen corresponding to the eyepiece optical system.

12. A head-mounted display device as claimed in claim 1, 2 or 3, wherein the head-mounted display device is a binocular head-mounted display device comprising:

a left eye eyepiece optical system; and a left eye display screen corresponding to the left eye eyepiece optical system;

a right eye eyepiece optical system; and a right eye display screen corresponding to the right eye eyepiece optical system.

13. A head-mounted display device as recited in claim 1, 2 or 3, wherein the eyepiece optical system comprises:

the lens comprises a first lens, a second lens and a third lens which are coaxially and sequentially arranged along the direction of an optical axis, wherein the first lens is close to the side of human eyes, the third lens is close to the side of an image source, and light rays of the image source are watched by the human eyes through the third lens, the second lens and the first lens in sequence;

the combined focal power of the first lens and the second lens is a positive value, and the surface of the second lens close to the image source side is convex to the image source direction;

the curvature directions of the two optical surfaces of the third lens are the same and are both concave to the direction of the image source.

14. A head-mounted display device as recited in claim 1, 2 or 3, wherein the eyepiece optical system comprises:

the lens comprises a first lens group and a second lens group which are coaxially and sequentially arranged along the direction of an optical axis from the observation side of human eyes to the display screen side, wherein the effective focal length of the first lens group is a negative value, and the effective focal length of the second lens group is a positive value;

the first lens group consists of two lenses, namely a fourth lens close to the human eye side and a fifth lens far away from the human eye side, the fourth lens is a biconvex positive lens, and the fourth lens is a negative lens; the optical surface of the fifth lens close to the human eye side is concave to the human eye side, and the curvature radius is a negative value;

the second lens group is composed of one or more lenses, wherein the second lens group at least comprises a sixth lens adjacent to the first lens group and a seventh lens, the sixth lens is a positive lens, and the seventh lens is positioned between the sixth lens and the display screen side.

15. A head-mounted display device as recited in claim 1, 2 or 3, wherein the eyepiece optical system comprises: the lens comprises a first lens group and a second lens group which are coaxially and sequentially arranged along the direction of an optical axis from the observation side of human eyes to the display screen side, wherein the effective focal length of the first lens group is a negative value, and the effective focal length of the second lens group is a positive value;

the first lens group consists of two lenses, namely an eighth lens close to the human eye side and a ninth lens far away from the human eye side, the eighth lens is a biconvex positive lens, and the ninth lens is a negative lens;

the second lens group is composed of one or more lenses, wherein the second lens group at least comprises a tenth lens adjacent to the first lens group, and the tenth lens is a positive lens;

the second lens group further comprises an eleventh lens and a twelfth lens, and the tenth lens, the eleventh lens and the twelfth lens are arranged in sequence from the human eye side to the micro display side;

the eleventh lens is located between the tenth lens and the display screen side.

16. A method of manufacturing an eyepiece optical system of a head mounted display device as recited in claim 1, comprising the steps of:

trimming the wide edge of the lens of the head-mounted display device;

wherein the ratio range of the minimum value of the reserved size of the lens after the broadside edge trimming and the maximum effective optical aperture of the lens is as follows: 0.22-0.66; the length and width ratio range corresponding to the effective display picture of the display screen is as follows: 1:1-16:3.

17. The process of claim 16, wherein the lens has a dimension D after broadside trimming, a dimension E after long side trimming, and an outer diameter B before processing; wherein B, D, E satisfies the following relation (3):

(3)；

and when the value of E/B is more than 0.92, the long-edge trimming processing is not carried out on the eyepiece optical system.

18. The process of claim 16, further comprising the step of: performing edge cutting processing on the long edge of the lens of the head-mounted display device; wherein,

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is 1.03-1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after edge cutting to the maximum effective optical aperture of the lens is as follows: greater than 0.80;

or further comprising the steps of: performing edge cutting processing on the long edge of the lens of the head-mounted display device; wherein,

when the ratio of the outer diameter of the lens to the maximum effective optical aperture is greater than 1.1, the range of the ratio of the minimum value of the reserved size of the long edge of the lens after being cut to the maximum effective optical aperture of the lens is as follows: greater than 0.9.