Source: https://patents.google.com/patent/JP2013065022A/en
Timestamp: 2019-12-12 00:37:26
Document Index: 700244030

Matched Legal Cases: ['art 113', 'art 112', 'art 113', 'art 113', 'art 112', 'art 111', 'art 113', 'art 111', 'art 111', 'art 111', 'art 111', 'art 12', 'art 113', 'art 112', 'art 200', 'art 111']

JP2013065022A - Display device - Google Patents
JP2013065022A
JP2013065022A JP2012228697A JP2012228697A JP2013065022A JP 2013065022 A JP2013065022 A JP 2013065022A JP 2012228697 A JP2012228697 A JP 2012228697A JP 2012228697 A JP2012228697 A JP 2012228697A JP 2013065022 A JP2013065022 A JP 2013065022A
JP2012228697A
JP5475083B2 (en
Tadaya Yamamoto
格也 山本
Kenichi Kasasumi
2011-03-25 Priority to JP2011067243 priority Critical
2011-03-25 Priority to JP2011067243 priority
2012-10-16 Application filed by Panasonic Corp, パナソニック株式会社 filed Critical Panasonic Corp
2012-10-16 Priority to JP2012228697A priority patent/JP5475083B2/en
2013-04-11 Publication of JP2013065022A publication Critical patent/JP2013065022A/en
2014-04-16 Publication of JP5475083B2 publication Critical patent/JP5475083B2/en
PROBLEM TO BE SOLVED: To provide a display device that compatibly enables the body size to be reduced and the screen for remote displaying of a virtual image to a user to be enlarged (widened in the angle of view).SOLUTION: A display device 1 comprises a laser beam source 101 that outputs a laser beam; an illuminating optical system 102 that emits the laser beam as an illuminating light beam; a spatial modulation element 103 that diffracts the illuminating light beam by displaying a diffraction pattern; and a fitting unit 111 to be fitted to a user's head. In a state in which the fitting unit 111 is fitted to the user's head, the positional relation between the spatial modulation element 103 and a supposed eyeball position 191a supposed as the position of the user's eyeball 190 is fixed. The spatial modulation element 103 displays as the diffraction pattern such a diffraction pattern as displays a virtual image to the user by causing the light beam diffracted in the diffraction pattern to reach the supposed eyeball position 191a.
The present invention relates to a head-mounted display device that displays information by diffracting laser light with a diffraction pattern by a computer generated hologram.
A head-mounted display (hereinafter referred to as “HMD”) is a device that displays information to a user while the user is wearing the head. In general, the HMD is desirably small and lightweight from the viewpoint of wearability, while it is desirable that the HMD has a large screen and high image quality from the viewpoint of display performance. Conventionally, the HMD has a method of displaying an enlarged virtual image to a user by optically enlarging an image displayed on a small liquid crystal panel or the like with a convex lens or a free-form surface prism (hereinafter referred to as “optical enlargement”). Method ”). For example, there is an “image display device” disclosed in Patent Document 1 as an optical enlargement type HMD.
On the other hand, in a display device using a computer generated hologram (hereinafter referred to as “CGH”), a diffraction pattern obtained by a computer using an image to be displayed as input data is displayed on a phase modulation type liquid crystal panel or the like. The liquid crystal panel is irradiated with laser light and diffracted, thereby reproducing the wavefront of the display light from the virtual image position and displaying the virtual image to the user. The CGH method has a feature that a three-dimensional stereoscopic image can be displayed in front of or behind the liquid crystal panel. For example, as a device for three-dimensional stereoscopic display by the CGH method, there is “Patent Document 2“ Device for Holographic Reconstruction of Three-dimensional Scene ”. Moreover, although it is not a CGH system, there also exists a prior example which displays a three-dimensional stereo image to a user with a diffraction pattern (refer patent document 3).
JP-A-8-240773 Special table 2008-541145 JP-A-6-202575
However, in the conventional optical enlargement method, the virtual screen displayed to the user is larger than the liquid crystal panel size and is larger than the distance to the liquid crystal panel while arranging a small liquid crystal panel near the user's eyeball to reduce the size of the main body. Even if an attempt is made to display far away, the magnifying optical system becomes large, and thus there is a problem that it is difficult to achieve both the downsizing of the display device and the large screen distant display.
Further, in the conventional CGH, the smaller the dot pitch of the liquid crystal panel displaying the diffraction pattern, the larger the diffraction angle. Therefore, as a result of using the liquid crystal panel with a fine dot pitch, the liquid crystal panel size becomes relatively small and large. There is a problem that is difficult to screen.
In Patent Document 2, a laser parallel light for irradiating a liquid crystal panel is provided with a plurality of light sources, so that a large screen (wide angle of view) is realized by irradiating from a plurality of angles, and in Patent Document 3, The scanning method that changes the incident angle of the laser parallel light that irradiates the liquid crystal panel with time has realized a large screen, but each method uses multiple light sources and scanning means to change the incident angle of the laser parallel light. This is necessary, and there is a problem for miniaturization of the main body.
The present invention solves the above-described conventional problems, and an object thereof is to provide a display device that can achieve both a reduction in size of a main body and a large screen (wide angle of view) by remote display of a virtual image displayed to a user. And
A display device according to one aspect of the present invention includes a light source that outputs laser light, an illumination optical system that emits the laser light as illumination light, and a spatial modulation element that diffracts the illumination light by displaying a diffraction pattern. A mounting portion for mounting on the user's head, and the position of the spatial modulation element and the user's eyeball is assumed in a state where the mounting portion is mounted on the user's head. The spatial modulation element displays a virtual image to the user as diffracted light diffracted by the diffraction pattern reaches the assumed eyeball position as the diffraction pattern. Such a diffraction pattern is displayed.
According to the display device of the present invention, it is possible to provide a display device that can achieve both downsizing and a large screen (wide angle of view) by distant display of a virtual image displayed to the user.
It is a figure which shows typically the structure of the head mounted display apparatus in Embodiment 1 of this invention. It is a block diagram which shows the electrical constitution of the display apparatus 1 shown by FIG. It is a figure which shows the illumination optical system which illuminates the spatial modulation element of the display apparatus shown by FIG. It is a figure which shows the structure of the reflective mirror of the display apparatus shown by FIG. It is a figure which shows the output window of the display apparatus shown by FIG. It is a figure explaining the positional relationship of an eyeball, a reflective mirror, a spatial modulation element, a virtual image, etc. It is a figure explaining the positional relationship of an eyeball, a reflective mirror, a spatial modulation element, a virtual image, etc. (A) is a figure which shows a virtual image, (b) is a figure which shows the diffraction pattern which implement | achieves the virtual image shown by (a). It is a figure which shows another illumination optical system from the illumination optical system shown by FIG. It is a block diagram which shows the electric constitution of the display apparatus in Embodiment 2 of this invention. It is a block diagram which shows the electric constitution of the display apparatus in Embodiment 3 of this invention. It is a block diagram which shows the electrical constitution of the display apparatus in Embodiment 4 of this invention. It is a block diagram which shows the electric constitution of the display apparatus in Embodiment 5 of this invention. It is a block diagram which shows the electrical constitution of the display apparatus in Embodiment 6 of this invention. It is a block diagram which shows the electrical constitution of the display apparatus in Embodiment 7 of this invention. It is a figure which shows the structure of the principal part of the display apparatus of Embodiment 7 of this invention. It is a figure which shows typically an example of the display apparatus of a shape different from glasses shape. It is a figure which shows the illumination optical system in the conventional display apparatus.
FIG. 1 is a diagram schematically showing a configuration of a head-mounted display device 1 according to Embodiment 1 of the present invention. FIG. 2 is a block diagram showing an electrical configuration of the display device 1 shown in FIG. FIG. 3 is a diagram showing an illumination optical system that illuminates the spatial modulation element of the display device 1 shown in FIG. FIG. 4 is a diagram showing the configuration of the reflection mirror of the display device 1 shown in FIG. FIG. 5 is a diagram showing an exit window of the display device 1 shown in FIG. The display device 1 according to the first embodiment has a glasses shape, and FIG. 1 is a view from above.
In FIG. 1, a light source 101 is a laser light source that outputs laser light. In FIG. 1, a semiconductor laser (laser diode) that outputs a laser beam having a green wavelength is used as a light source. Note that a single color of red or blue may be used, or three colors of red, green, and blue may be combined for color display. Further, a laser other than a semiconductor laser may be used, or a combination of a semiconductor laser and others may be used. A combination of an infrared semiconductor laser and a second harmonic generation (SHG) element that converts infrared light into green may be used. The light source 101 outputs laser light having a spectral width of 0.1 nm or more, for example.
The illumination optical system 102 emits illumination light in which the wavefront shape and intensity distribution of the laser light from the light source 101 are changed. In the first embodiment, as shown in FIG. 3, the illumination optical system 102 includes a convex lens 511 that converts diffused laser light into convergent light, and a neutral density filter (ND filter) 512 that attenuates the intensity of the laser light. including. The wavefront shape of the illumination light may be changed by a lens, a mirror, or an element that can be changed dynamically, such as a liquid crystal lens. An optical system that changes the intensity distribution may also be included. A filter for removing unnecessary illumination light may be included. The illumination optical system 102 will be further described later.
The spatial modulation element 103 diffracts the illumination light from the illumination optical system 102 by displaying a diffraction pattern. In the first embodiment, a phase modulation reflective liquid crystal panel is used as the spatial modulation element 103. The spatial modulation element 103 is not limited to the liquid crystal panel, and may be another display element as long as it can diffract the illumination light by displaying a diffraction pattern.
The reflection mirror 104 reflects the diffracted light from the spatial modulation element 103 toward the user's eyeball 190. In the first embodiment, a Fresnel lens 742 is used as the reflection mirror 104 as shown in FIG. The reflection mirror 104 is a semi-transmissive Fresnel mirror by depositing a thin metal film on the Fresnel lens 742. The Fresnel lens 742 is bonded to the lens portion 113 of the front portion 112 with an adhesive 741.
In FIG. 4, a Fresnel lens 742, an adhesive 741, and a lens unit 113 are arranged in order from the eyeball 190 side (lower side in FIG. 4) to the opposite side (upper side in FIG. 4). The Fresnel lens 742 and the lens part 113 bonded with the adhesive 741 are, as the boundary surfaces, in order from the eyeball 190 side to the opposite side, the surface 104a on the eyeball 190 side, the Fresnel lens surface 104b, the adhesive surface 104c, and the opposite surface. 104d. The diffracted light from the spatial modulation element 103 is reflected by the Fresnel lens surface 104 b and travels toward the pupil 191. As the refractive index of the Fresnel lens 742 and the refractive index of the layer of the adhesive 741 are closer, there is an effect that the distortion of the transmitted outside scene can be reduced. As the Fresnel lens 742, a prism sheet having an optical magnification of 1 may be used, or a Fresnel lens having an optical magnification may be used.
Instead of using the reflection mirror 104, the liquid crystal panel may be an HMD that allows the user to directly view the liquid crystal panel. Note that the reflection mirror may be a lens type or a diffraction grating such as a hologram. Further, the reflection mirror 104 of the first embodiment transmits the outside scene while reflecting the display light, but may be configured not to transmit the outside scene. In this embodiment, the reflection mirror 104 is disposed on the surface of the lens portion 113 of the front portion 112, but the reflection mirror 104 may be disposed inside the lens portion 113.
The eyeball 190 illustrates an eyeball at the assumed eyeball position of the display device 1. In the first embodiment, the assumed eyeball position is the pupil center 191a of the pupil 191 of the eyeball 190 when the user is wearing the display device 1. Note that the assumed position of the eyeball may be slightly deviated from the pupil center 191a. The diffracted light reflected by the reflection mirror 104 forms an image on the retina via the pupil 191 of the eyeball 190 at the assumed position of the eyeball. As a result, an image is displayed to the user. In other words, the user can visually recognize the image. An eyeball center 192 in FIG. 1 is the center position of the eyeball 190 and also the center of rotation of the eyeball 190. When the user wears the display device 1 (that is, when the temple unit 111 is put on the ear), the positional relationship between the spatial modulation element 103 and the assumed eyeball position is fixed. In consideration of individual differences in the position of the eyeball 190 with respect to the head by the user and a mounting deviation of the display device 1, an allowable error may be provided in the assumed eyeball position, and a function for adjusting the assumed eyeball position is provided. May be.
The control unit 105 includes a light source control unit 11 and a communication control unit 12. The light source control unit 11 controls driving of the light source 101 to turn on and off the light source 101 and adjust the intensity of the laser light output from the light source 101 so that an appropriate amount of light enters the eyeball 190. The communication control unit 12 has a wireless communication function and acquires a diffraction pattern transmitted from an external device. The communication control unit 12 controls the spatial modulation element 103 to display the acquired diffraction pattern on the spatial modulation element 103 (the liquid crystal panel in the first embodiment). Further, the communication control unit 12 may change the diffraction pattern. Further, the control unit 105 may control the battery 106, or may control the illumination optical system 102 or the reflection mirror 104 when it can be controlled.
The battery 106 supplies power to each unit of the display device 1 such as the control unit 105 and the spatial modulation element 103. The battery 106 in FIG. 1 is rechargeable and is charged when the user is not wearing the display device 1. The battery 106 is arranged near the rear end of the temple portion 111 on the ear side, so that the overall weight balance can be brought closer to the ear side and the sliding of the front portion 112 can be reduced. The battery 106 may not be rechargeable and may be supplied with power while the display device 1 is in use. Further, the display device 1 may not be provided with the battery 106 but may be supplied with power from the outside. Further, instead of the battery 106, the display device 1 may include a member having a power generation function.
Here, the illumination optical system 102 will be described in more detail with reference to FIG. The illumination optical system 102 includes the convex lens 511 and the neutral density filter 512 as described above. As shown in FIG. 3, the illumination optical system 102 converges the laser light output from the light source 101 to the pupil center 191 a of the pupil 191 of the eyeball 190 by the convex lens 511. The neutral density filter 512 reduces the intensity of the laser light so that the intensity is suitable for visual recognition of the eyeball 190. The illumination light emitted from the illumination optical system 102 is diffracted by the diffraction pattern displayed on the spatial modulation element 103. The spatial modulation element 103 is a reflection type element in this embodiment, but is illustrated as a transmission type element in FIG. 3 for convenience of illustration. Further, in this embodiment, as shown in FIG. 1, the spatial modulation element 103 is disposed obliquely with respect to the optical axis of the illumination optical system 102. However, for convenience of illustration, in FIG. Are arranged vertically.
FIG. 18 is a diagram illustrating an illumination optical system in the examples described in the background art (Patent Documents 2 and 3). In FIG. 18, the parallel illumination light is diffracted by the spatial modulation element 900 and reaches the pupil 191 of the user's eyeball 190. In order to diffract the light near the end of the spatial modulation element 900 toward the pupil 191, a diffraction angle 901 is required as shown in FIG.
On the other hand, in this embodiment, as shown in FIG. 3, the diffraction angle 501 is sufficient as the diffraction angle near the end of the spatial modulation element 103. Since the illumination optical system 102 of this embodiment uses illumination light as convergent light to the center of the pupil of the pupil 191, the diffraction angle 501 may be smaller than the diffraction angle 901 (FIG. 18).
In this embodiment, as a result of making the required diffraction angle smaller than that shown in FIG. 18, the dot pitch of the spatial modulation element 103 displaying the diffraction pattern may be larger than that of the spatial modulation element 900 shown in FIG. As a result, if the spatial modulation element has the same number of pixels, a spatial modulation element larger than the conventional spatial modulation element 900 can be used, so that a large screen can be achieved. Alternatively, even when a spatial modulation element having the same size as the conventional spatial modulation element 900 is used, the screen can be enlarged by increasing the optical magnification of the reflection mirror 104.
Thus, the effect of reducing the required diffraction angle by the convergent light illumination becomes more effective as the size of the spatial modulation element 103 is larger than the size of the pupil 191. In addition, when the spatial modulation element 103 is optically enlarged by the reflection mirror 104 or the like, the larger the size of the virtual image of the spatial modulation element 103 compared to the size of the pupil 191, the more effective. The convergent light illumination on the eyeball 190 is particularly effective in a display device in which the positional relationship between the spatial modulation element 103 and the eyeball 190 is substantially fixed, such as the display device 1. When the positional relationship between the spatial modulation element 103 and the eyeball 190 is not fixed, a mechanism for changing the convergence center is separately required.
Returning to FIG. 1, the glasses-shaped display device 1 includes a temple portion 111 at the temporal region and a front portion 112 in front of the eyes. A cavity is formed inside the temple unit 111, and the light source 101, the illumination optical system 102, the spatial modulation element 103, the control unit 105, and the battery 106 are disposed in the cavity. The temple portion 111 is provided with an emission window 114 so that diffracted light from the spatial modulation element 103 is emitted to the reflection mirror 104.
As shown in FIG. 5, the periphery of the emission window 114 is painted black, for example, so that the periphery of the spatial modulation element 103 arranged in the temple portion 111 is shielded from light. Accordingly, unnecessary diffracted light generated when light other than illumination light from the illumination optical system 102 enters the spatial modulation element 103 can be prevented from reaching the eyeball 190.
In addition, since the diffraction by the spatial modulation element 103 is performed not in the lens unit 113 but in the temple unit 111, there is an effect that it is not necessary to take measures against unnecessary diffracted light in the lens unit 113. Since the countermeasure against unnecessary diffracted light becomes easy, there is an effect that the display device 1 with less unnecessary diffracted light can be realized even in the outdoors or at night when it is generally easy to generate unnecessary diffracted light. Even if the display device 1 does not display a virtual image and is used as simple glasses, there is an effect that a state with less unnecessary light can be realized.
As shown in FIG. 5, the shape of the exit window 114 is a trapezoidal shape, and the vertical side on the ear side (right side in FIG. 5) is longer than the vertical side on the front side (left side in FIG. 5). As a result, there is an effect that the left and right heights of the virtual image can be aligned by entering the reflection mirror 104 obliquely and reflecting it to the eyeball 190.
Note that the shape of the exit window 114 is not limited to a trapezoid, but may be a circle such as a circle, an ellipse, or a rectangle, other polygons, or a free-form surface. The exit window 114 may have a hole. If the exit window 114 is perforated, there is an effect effective for ventilation and exhaust heat inside the temple portion 111. The exit window 114 may have a transparent lid. Providing the lid on the exit window 114 has an effect of reducing entry of dust and the like and preventing contamination. In the case where a lid is provided on the exit window 114, the transparent lid may have a lens function. The lid of the exit window 114 may be a lens that corrects aberrations that occur due to being incident on the reflection mirror 104 obliquely. For example, the coma aberration may be corrected by arranging a wedge prism between the lid of the exit window 114 or between the lid and the spatial modulation element 103.
The front part 112 includes a lens part 113, and the reflection mirror 104 is disposed on the surface of the lens part 113. Further, the front part 112 and the temple part 111 may be bent in order to improve portability. In this case, the bending position may be the end of the temple portion 111 or may be closer to the ear than the spatial modulation element 103. The lens unit 113 may be a lens with a power for myopia, or a lens for correcting hyperopia and astigmatism, like a normal eyeglass lens. Moreover, the lens part 113 may reduce the transmittance | permeability like sunglasses and may have a polarization function. In addition, the lens unit 113 may prevent reflection of unnecessary light or may include a film having a function of preventing contamination.
In the first embodiment shown in FIG. 1, the virtual image is displayed only on one eye, but the present invention is not limited to this. For example, a spatial modulation element may be provided in the temple portion 115 on the opposite side to provide a binocular display device. One spatial modulation element may be shared by both eyes. Further, a plurality of spatial modulation elements may be used for a single eye.
A distance A (FIG. 6) indicated by reference numeral 121 in FIG. 1 indicates the distance from the assumed eyeball position of the user (in this embodiment, the pupil center 191 a as described above) to the reflection mirror 104. A distance B (FIG. 6) indicated by a reference numeral 122 in FIG. 1 indicates a distance from the reflection mirror 104 to the spatial modulation element 103. The sum of the distance A and the distance B is referred to as a distance (or optical axis distance) from the assumed position of the eyeball to the spatial modulation element 103.
6 and 7 are diagrams illustrating the positional relationship between the eyeball 190, the reflection mirror 104, the spatial modulation element 103, a virtual image, and the like. FIG. 8A is a diagram showing a virtual image, and FIG. 8B is a diagram showing a diffraction pattern for realizing the virtual image shown in FIG. 8A.
As shown in FIG. 6, an eyeball 190, a reflection mirror 104, and a spatial modulation element 103 are arranged. When the optical magnification of the reflection mirror 104 is 1, the virtual image 202 of the spatial modulation element 103 is at the position shown in FIG. The distance 210 from the center of the pupil of the pupil 191 of the eyeball 190 to the virtual image 202 is the sum of the distance A from the eyeball 190 to the reflection mirror 104 and the distance B from the reflection mirror 104 to the spatial modulation element 103. It is equal to the distance from the pupil center of 191 to the spatial modulation element 103. In the example of FIG. 6, the spatial modulation element 103 is arranged obliquely with respect to the optical axis 220, but the distance in this case is a distance based on the center point of the spatial modulation element 103. A point other than the center may be used as a reference.
Further, as shown in FIG. 7, when the optical magnification of the reflection mirror 104 is larger than 1, the virtual image 302 of the spatial modulation element 103 is at the position shown in FIG. In this case, the distance 310 from the pupil center of the pupil 191 of the eyeball 190 to the virtual image 302 of the spatial modulation element 103 is longer than the distance 210 in FIG. 6, and the virtual image 302 is larger than the virtual image 202.
In the display device 1 of the present embodiment, the spatial modulation element 103 is disposed inside the temple portion 111 as shown in FIG. For this reason, the distance 210 from the pupil center 191a of the pupil 191 of the eyeball 190 to the spatial modulation element 103 is about 7 cm. The size of the distance 210 varies slightly depending on the type of eyeglass shape, but when the spatial modulation element 103 is arranged in the temple portion 111, it is generally within 10 cm, and the lower limit is about 2 cm or more.
On the other hand, the “clear vision distance” indicated by reference numeral 211 in FIGS. 6 and 7, which is the shortest distance by which the user's eyeball 190 can reasonably see the object, differs for each user, but is generally about 25 cm. ing. In the example of FIG. 6, the virtual image 202 of the spatial modulation element 103 is closer than the clear vision distance 211. For this reason, it is difficult for the user to visually recognize the diffraction pattern or image displayed on the spatial modulation element 103.
In the conventional optical magnifying method, it is necessary to provide a magnifying optical system between the eyeball and the spatial modulation element, so that the position of the virtual image of the spatial modulation element must be longer than the clear viewing distance. There was a problem to do.
In the present embodiment, unlike the conventional method in which an image to be displayed to the user is displayed on the spatial modulation element, a diffraction pattern is obtained by calculating the CGH so that the virtual image desired to be displayed to the user appears farther than the clear vision distance. The spatial modulation element 103 displays the diffraction pattern. Thereby, even if the distance to the virtual image of the spatial modulation element 103 is shorter than the clear vision distance, a virtual image can be displayed at a position far from the clear vision distance. As a result, even if the spatial modulation element 103 is arranged in the temple portion 111, it is not necessary to increase the optical magnification of the magnifying optical system to increase the size, so that the display device 1 that is a small and glasses-type HMD can be realized.
In the example of FIG. 6, by displaying the diffraction pattern 402 (FIG. 4) on the spatial modulation element 103, the user views, for example, the virtual image 401 (FIG. 4) at the position of the virtual image 201 farther than the clear vision distance 211. be able to. Here, the distance 212 from the eyeball 190 to the virtual image can be changed by the calculation result of the diffraction pattern, and can be set to 200 cm, for example. As a result, the distance 212 can be longer than the clear vision distance 211. In the example of FIG. 7 as well, the distance 312 from the pupil 191 of the eyeball 190 to the virtual image 301 can be made longer than the clear vision distance 211.
In the present embodiment, the temple portion 111 corresponds to an example of a mounting portion, the pupil center 191a of the pupil 191 corresponds to an example of an assumed eyeball position, the exit window 114 corresponds to an example of a transmission window, and the surface 104a assumes an eyeball. The surface 104d corresponds to an example of a position-side surface, the surface 104d corresponds to an example of an opposite surface, and the communication control unit 12 corresponds to an example of a receiving unit.
Thus, the display device 1 according to the first embodiment arranges the spatial modulation element 103 so that the optical axis distance from the pupil center 191a of the pupil 191 that is the assumed position of the eyeball to the spatial modulation element 103 is 10 cm or less, The spatial modulation element 103 displays a diffraction pattern that virtually displays the image 201 farther than the distance from the pupil center 191 a to the virtual image 202 of the spatial modulation element 103.
With this configuration, the spatial modulation element 103 can be disposed near the eyeball 190. As a result, there is an effect that the display device 1 having a small size such as a glasses shape and excellent in head wearability can be realized. There is an effect that the illumination optical system 102 arranged in the temple portion 111 can be made smaller. At that time, in order to use the CGH method, it is not necessary for the user's eyeball 190 to focus on the virtual image 202 of the spatial modulation element 103, and the image can be seen by focusing on the farther virtual image 201. There is an effect that the spatial modulation element 103 can be brought close to the eyeball 190 and the display device 1 can be miniaturized without being restricted by the focus adjustment capability.
Since there is no need to view an image on the spatial modulation element 103 as in the conventional optical enlargement method, the necessity for increasing the magnification is also reduced, so that the occurrence of aberration can be suppressed and the image quality can be improved. Further, since the spatial modulation element 103 can be brought close to the eyeball 190, there is an effect that the screen can be enlarged with a wide angle of view. In addition, since the distance to the virtual image 201 can be increased by calculation of CGH, there is an effect that the focus adjustment fatigue of the eyeball 190 can be reduced. In addition, since it is possible to realize the display according to the characteristics of each individual's eyes such as myopia power and astigmatism by calculation of CGH, the illumination optical system 102 can be simplified and shared, and the size, cost, and reliability can be improved. There is a connected effect.
Further, in the display device 1 according to the first embodiment, the distance from the position of the pupil 191 to the virtual image 202 of the spatial modulation element 103 is less than the clear viewing distance 25 cm, which is the shortest distance at which the user's eyeball 190 can reasonably see the object. The spatial modulation element 103 is arranged so as to be short, and the spatial modulation element 103 displays a diffraction pattern that increases the distance from the position of the pupil 191 to the virtual image 201 that is visually recognized by the user.
With this configuration, the spatial modulation element 103 can be arranged so close that the eyeball 190 is not in focus, and the virtual image 201 can be displayed far away where the eyeball 190 is in focus while reducing the size and size of the main body. Further, even when a lens or a mirror for optically enlarging the spatial modulation element 103 is used, the enlargement magnification can be reduced. As a result, there is an effect that the display device 1 having a smaller size and higher image quality can be realized.
In addition, the display device 1 according to the first embodiment includes a reflection mirror 104 that reflects the diffracted light diffracted by the spatial modulation element 103 to the position of the pupil 191, and the display device 1 has a glasses shape, and has a light source. 101, the illumination optical system 102, and the spatial modulation element 103 are disposed inside the temple unit 111, and the reflection mirror 104 is disposed on the surface of the lens unit 113 of the front unit 112.
With this configuration, there is an effect that the shape of the display device 1 can be brought close to glasses. In addition, there is an effect of increasing the shape freedom of the glasses shape. In particular, there is an effect that the degree of freedom of shape of the front portion 112 of the glasses can be increased. Since the lens unit 113 only needs to have the reflection mirror 104, the lens unit 113 has an effect of increasing the transparency. There is also an effect that the degree of freedom of the shape of the lens portion 113 can be increased. There is an effect that the transmission performance and reflection performance of the lens unit 113 and the reflection mirror 104 can be designed separately from the characteristics of the spatial modulation element 103.
When the reflection mirror 104 is not a diffraction mirror, there is an effect that the influence of diffraction such as stray light or diffraction shift due to a difference in wavelength can be reduced. Since the light source 101, the illumination optical system 102, and the spatial modulation element 103 are arranged inside the temple part 111, the parts other than the temple part 111 can be miniaturized and the design flexibility can be increased. In addition, by miniaturizing the illumination optical system 102 of the temple part 111, there is an effect that the temple part 111 can be miniaturized. If the illumination optical system 102 is designed to be thin, the temple portion 111 can be made thin. For example, there is an effect that the thickness of the temple portion 111 can be made smaller than the height.
Further, in the display device 1 according to the first embodiment, the spatial modulation element 103 is a reflective element, and illumination light from the illumination optical system 102 is incident on the spatial modulation element 103 and is reflected obliquely. The display device 1 does not include a separation optical system that separates incident light and reflected light. The spatial modulation element 103 displays a diffraction pattern in which the display surface of the virtual image 201 displayed to the user is closer to a plane perpendicular to the optical axis of the diffracted light than the surface of the spatial modulation element 103.
With this configuration, since a reflective element is used as the spatial modulation element 103, there is an effect that the use efficiency of light can be increased and power can be saved as compared with the case where a transmissive element is used. Further, since the area other than the pixels of the spatial modulation element 103 can be easily reduced, there is an effect that the image quality can be improved, and there is an effect that the element can be downsized and the dot pitch can be reduced. Since the separation optical system is not included, there is an effect that a small display device 1 can be realized. Further, since the separation optical system is not included, there is an effect that the temple portion 111 can be miniaturized and the thickness of the temple portion 111 can be reduced. Even if the spatial modulation element 103 is inclined with respect to the optical axis, there is an effect that the virtual image 201 can be brought close to the vertical by the calculation of the CGH. By performing aberration correction of the illumination optical system 102 by calculating CGH, there is an effect that the illumination optical system 102 can be reduced in size. Since the spatial modulation element 103 may be disposed obliquely, there is an effect that the degree of freedom in designing the temple portion 111 can be increased, and for example, the thickness of the temple portion 111 can be reduced. Further, by arranging the spatial modulation element 103 obliquely, the dot pitch on the basis of the optical axis is narrowed. As a result, there is an effect that the diffraction angle can be widened to widen the angle of view and increase the image quality.
In the display device 1 according to the first embodiment, the illumination light emitted from the illumination optical system 102 to the spatial modulation element 103 is convergent light to the pupil center 191a.
With this configuration, the required diffraction angle in the spatial modulation element 103 can be reduced. As a result, there is an effect that the display device 1 having a wider angle of view and a larger screen can be realized. In addition, a simple illumination optical system 102 that does not need to distribute parallel light as in the conventional example can be realized, and the size can be reduced. As a result of converging light on the pupil center 191a of the eyeball 190, there is an effect that the image quality and the angle of view can be increased by concentrating on the position of the pupil 191. Unnecessary light other than the position of the eyeball 190 is reduced, and the required amount of light is reduced. Therefore, there is an effect that further miniaturization, higher luminance, and power saving can be realized. Since power saving also reduces the size of the battery 106, there is an effect that the size and weight can be reduced.
Further, in the display device 1 according to the first embodiment, the light source 101 has a spectral width of laser light output to the illumination optical system 102 of 0.1 nm or more.
With this configuration, the diffraction angle required in the spatial modulation element 103 can be reduced by the convergent light illumination of the illumination optical system 102. For this reason, there is an effect that the light source 101 that outputs laser light having a wider spectrum width can be used. Thereby, there is an effect that the light source 101 can be reduced in size and cost.
In the display device 1 according to the first embodiment, the amount of reflected light reflected from the spatial modulation element 103 toward the user's eyeball 190 by the reflection mirror 104 is transmitted through the reflection mirror 104 and transmitted to the user. The amount of transmitted light output in the opposite direction to the eyeball 190 is within 100 times.
With this configuration, there is an effect that the display device 1 that can display by reflection while increasing the transmittance of the lens unit 113 can be realized. By setting it within 100 times, the ratio of the amount of transmitted light of display light to the amount of reflected light can be up to two digits. Therefore, there is an effect that the amount of unnecessary transmitted light of the display light can be suppressed without reducing the luminance of the virtual image 201 due to the reflected light. Thereby, even when there is a user or an eyeball other than the user at a place other than the assumed position of the eyeball, there is an effect that the incident light to the eyeball can be reduced and uncomfortable feeling can be reduced. In addition, there is an effect that the output of the light source 101 can be reduced, and miniaturization and power saving can be achieved. Note that the lower limit of the ratio of the amount of transmitted light to the amount of reflected light is not particularly limited. However, for example, by setting the ratio to 10 times or more, an outside scene can be suitably viewed through the reflection mirror 104.
In the display device 1 according to the first embodiment, when the incident angle of the diffracted light incident from the spatial modulation element 103 is compared with the reflection angle of the diffracted light reflected toward the pupil 191, the reflection of the reflection mirror 104 is reflected. In the region, the region where the incident angle is larger than the reflection angle is wider than the region where the incident angle is smaller than the reflection angle. Further, in the reflection region of the reflection mirror 104, a region where the horizontal incident angle is larger than the vertical incident angle in a state where the user wearing the temple portion 111 on the head is upright, the horizontal incident angle is vertical. It is wider than the area smaller than the incident angle.
With this configuration, there is an effect that the inclination of the lens unit 113 and the shape of the temple unit 111 can be made similar to conventional glasses without an HMD function. There is also an effect that the left and right positions of the virtual image 201 can be brought closer to the front of the user. The position of the spatial modulation element 103 of the temple portion 111 can be closer to the front of the temple portion 111, and there is an effect that a temple shape with a height closer to the front lens portion 113 than to the ear of the temple portion 111 can be realized. Further, there is an effect that it is possible to realize the display device 1 in which part of the face around the user's eyes located between the spatial modulation element 103 and the reflection mirror 104 is not shielded from the display light directed from the spatial modulation element 103 to the reflection mirror 104. is there.
Note that the optical magnification of the reflecting mirror 104 may be different between the horizontal direction and the vertical direction. By making the horizontal magnification of the reflecting mirror 104 larger than the magnification in the vertical direction, it is possible to realize a virtual image 201 having a wide width, and by arranging the spatial modulation element 103 obliquely with respect to the optical axis of the illumination light. There is also an effect that priority can be given to the narrow width.
In the display device 1 according to the first embodiment, the reflection mirror 104 includes a Fresnel lens 742. The Fresnel lens 742 and the lens unit 113 bonded by the adhesive 741 have a face side surface 104a, a Fresnel lens surface 104b, an adhesive surface 104c, and an outer surface 104d as boundary surfaces in order from the face side. The refractive index of the medium (that is, Fresnel lens 742) between the face side surface 104a and the Fresnel lens surface 104b is equal to the refractive index of the medium (that is, the adhesive 741) between the Fresnel lens surface 104b and the adhesive surface 104c.
With this configuration, there is an effect that the shape and inclination of the lens unit 113 can be brought close to those of conventional glasses without an HMD function. There is an effect that the shape of the reflection mirror 104 can be reduced and the incident angle and reflection angle can be freely designed. Display device 1 in which diffracted light from spatial modulation element 103 arranged in temple portion 111 is reflected as if coming from the front of the user, and transmitted light from the outside world passes straight and suppresses distortion of the outside scene. There is an effect that can be realized. Further, since the Fresnel lens 742 is used for the reflection mirror 104 instead of the diffraction element, there is an effect that the influence of unnecessary diffracted light and the influence of diffraction angle change can be avoided.
In the display device 1 of the first embodiment, an element having one or more malfunctioning pixels may be used as the spatial modulation element 103.
With this configuration, there is an effect that a low-cost display device 1 using a lower-cost spatial modulation element 103 can be realized. Even if one pixel of the diffraction pattern is defective, the overall noise of the virtual image 401 is only slightly increased, and one pixel of the virtual image 401 is not lost. Therefore, the display device 1 in which the influence of the malfunctioning pixel is not localized is realized. There is an effect that can be done.
In addition, the display device 1 according to the first embodiment includes a communication control unit 12. The communication control unit 12 receives a diffraction pattern from the outside through wireless communication and causes the spatial modulation element 103 to display the received diffraction pattern. .
With this configuration, the diffraction pattern is not calculated in the main body of the display device 1. As a result, the display device 1 can be reduced in size and weight. In addition, there is an effect that heat generation of a circuit for calculating a circuit pattern can be reduced. Further, since the battery 106 is provided, there is an effect that the wireless display device 1 having no control line or power supply line can be realized. Further, since the wireless display device 1 can save power, there is an effect of extending the continuous use time until the battery 106 is charged.
In the first embodiment, information that may lead to wavelength variation of illumination light may be transmitted from an external device through wireless communication. And the communication control part 12 may change the acquired diffraction pattern based on the received information, and may reduce the influence of a wavelength fluctuation. Thereby, there is an effect that image quality deterioration due to environmental change or the like can be reduced. The information to be transmitted may include the temperature of the optical system such as the light source 101, the air temperature, the state of the laser return light, the laser intensity, the diffraction angle, or the like, or a change thereof. The transmission from the external device may be performed within a certain time after the power of the display device 1 is input.
In the first embodiment, as shown in FIG. 3, the illumination optical system 102 focuses the illumination light on the pupil center 191a of the pupil 191 of the eyeball 190. However, the present invention is not limited to this. Absent. For example, the illumination light may be converged to the center of the eyeball 190.
FIG. 9 is a diagram showing an illumination optical system different from the illumination optical system shown in FIG. Although the illumination light is convergent light to the eyeball 190 as in FIG. 3, the convergence center of the illumination light is not the center of the pupil but the eyeball center 192 of the eyeball 190. The larger the virtual image of the spatial modulation element 103 and the wider the angle of view of the virtual image, the more the eyeball 190 rotates and the pupil moves when the end of the virtual image is viewed in the central visual field. For example, when the diffracted light from the center of the spatial modulation element 103 in FIG. 9 is viewed in the central visual field, the pupil is at the position 621, but when the diffracted light from the upper end of the spatial modulation element 103 is viewed in the central visual field. The pupil moves to position 622.
Therefore, the width 612 of the convergent light at the pupil position is desirably wider than the pupil size so as to include the pupils at the positions 621 and 622. Here, as shown in FIG. 9, the illumination light is converged light to the eyeball center 192, and the width 613 at the pupil position of the diffraction range corresponding to the diffraction angle 601 is made smaller than the width 612. There is an effect that a required diffraction angle can be reduced in the spatial modulation element 103. If the required diffraction angle can be reduced, as described above, the dot pitch expansion of the spatial modulation element 103 can be allowed and the screen can be further enlarged. Further, as shown in FIG. 9, the width 612 of the convergent light at the pupil position is smaller than the width 611 of the spatial modulation element 103. In the form shown in FIG. 9, the eyeball center 192 corresponds to an example of an assumed eyeball position, the width 611 of the spatial modulation element 103 corresponds to an example of W1, and the width 612 of convergent light at the pupil position corresponds to an example of W2. The width 613 of the diffraction range at the pupil position corresponds to an example of W3.
9 has a width 611 of the spatial modulation element 103, a width 612 of the convergent light at the user's pupil position, and an upper limit of the diffraction angle determined according to the definition of the diffraction pattern stripes. In the width 613 of the diffraction range at the pupil position, the width 612 is equal to or smaller than the width 611 and equal to or larger than the width 613.
With this configuration, there is an effect that a display device with a wider angle of view can be realized. There is an effect that a larger spatial modulation element 103 can be used. There is an effect that the virtual image can be continuously displayed even if the eyeball 190 is rotated. There is also an effect that the image quality at the gazing point (central visual field) can be improved over the peripheral visual field.
In the first embodiment, as shown in FIG. 3, the illumination optical system 102 converges the illumination light on the pupil center 191a of the eyeball 190. In the embodiment shown in FIG. Although it is made to converge on the eyeball center 192 of 190, this invention is not limited to this. For example, the illumination optical system 102 may make the position on the line segment from the pupil center 191a to the eyeball center 192 the convergence center of the illumination light.
With this configuration, when the convergence center of the illumination light is at the pupil center 191a, there is an effect that it is possible to realize the display device 1 that prioritizes display performance when the pupil 191 is in front of the user's head. When the convergence center of the illumination light is at the eyeball center 192, there is an effect that the display device 1 that prioritizes display performance when the eyeball 190 rotates to visually recognize a virtual image can be realized. By setting the convergence center of the illumination light to a position on the line segment from the pupil center 191a to the eyeball center 192, there is an effect that the balance can be freely determined.
Furthermore, in the first embodiment, the illumination optical system 102 is configured so that the convergence center of the illumination light is different between the horizontal direction and the vertical direction, and the convergence center in the horizontal direction is closer to the eyeball center 192 than the convergence center in the vertical direction. The illumination light may be converged. That is, the illumination optical system 102 may vary the degree of convergence of illumination light between the horizontal direction and the vertical direction.
With this configuration, there is an effect that the display device 1 suitable for a horizontally long virtual image can be realized.
FIG. 10 is a block diagram showing an electrical configuration of the display device according to Embodiment 2 of the present invention. In the second embodiment, the same reference numerals are assigned to the same elements as those in the first embodiment. Hereinafter, the second embodiment will be described focusing on differences from the first embodiment.
The display device 1 a according to the second embodiment shown in FIG. 10 is the same as the display device 1 according to the first embodiment shown in FIG. 2, but the control unit 105 includes an element control unit 13 instead of the communication control unit 12. The other configuration of the second embodiment is the same as that of the first embodiment.
The element control unit 13 calculates a diffraction pattern (for example, the diffraction pattern 402 illustrated in FIG. 8B) from a desired virtual image (for example, the virtual image 401 illustrated in FIG. 8A). The element control unit 13 controls the spatial modulation element 103 to display the calculated diffraction pattern on the spatial modulation element 103.
The method by which the element control unit 13 obtains the diffraction pattern 402 from the virtual image 401 may be a general method for CGH. For example, in the point filling method, the intensity and phase of the wavefront at each pixel position of the spatial modulation element 103 are obtained from the intensity and phase of the wavefront of light emitted from each pixel of the virtual image, and each pixel of the spatial modulation element 103 is obtained. A diffraction pattern to be displayed on the phase modulation type spatial modulation element 103 can be generated by converting the obtained two-dimensional vector value of intensity and phase into a one-dimensional phase value for each time (see Patent Document 2). In the point filling method, the distance from the virtual image to the spatial modulation element 103 and the divergence and convergence degree of the laser light that illuminates the spatial modulation element 103 can be freely set and calculated. Further, in order to increase the speed of the point filling method, a diffraction pattern calculation method using a fast Fourier transform (FFT) in part may be used. In the present embodiment, the element control unit 13 corresponds to an example of a calculation unit.
In the second embodiment, the same effect as in the first embodiment can be obtained. As shown in FIG. 9, when the width 613 is smaller than the width 612, the method of calculating the diffraction pattern by the element control unit 13 may be simplified. For example, instead of applying the pixel value at the upper end of the virtual image displayed to the user to the entire diffraction pattern displayed on the spatial modulation element 103, the pixel value is applied only to a part of the upper part of the diffraction pattern, and the lower part of the diffraction pattern is calculated. Then, it may not be used. Thereby, the calculation amount for calculating the diffraction pattern can be reduced.
FIG. 11 is a block diagram showing an electrical configuration of the display device according to Embodiment 3 of the present invention. In the third embodiment, the same reference numerals are assigned to the same elements as in the first and second embodiments. Hereinafter, the third embodiment will be described focusing on differences from the first and second embodiments.
The display device 1b according to the third embodiment shown in FIG. 11 includes an element control unit 13a instead of the communication control unit 12 in the display device 1 according to the first embodiment shown in FIG. An information acquisition unit 107 is provided. The other configuration of the third embodiment is the same as that of the first embodiment.
The diffraction angle information acquisition unit 107 acquires information that leads to a change in the diffraction angle in the spatial modulation element 103. In this embodiment, the diffraction angle information acquisition unit 107 includes a temperature sensor 21, a timer 22, and optical sensors 23 and 24, for example. The temperature sensor 21 detects the temperature of the light source 101. The timer 22 counts the lighting time of the light source 101. The optical sensor 23 detects the intensity of the laser light output from the light source 101. The optical sensor 24 detects the diffraction angle of the diffracted light diffracted by the spatial modulation element 103.
The element control unit 13a calculates a diffraction pattern (for example, the diffraction pattern 402 illustrated in FIG. 8B) from a desired virtual image (for example, the virtual image 401 illustrated in FIG. 8A). The element control unit 13a changes the diffraction pattern using the value detected by the diffraction angle information acquisition unit 107. The element control unit 13 a controls the spatial modulation element 103 to display the changed diffraction pattern on the spatial modulation element 103.
When the temperature of the light source 101 rises and the wavelength of the laser light output from the light source 101 changes, the diffraction angle of the diffracted light diffracted by the spatial modulation element 103 changes. Further, when the lighting time of the light source 101 becomes longer, the temperature of the light source 101 rises, and when the intensity of the laser light output from the light source 101 increases, the temperature of the light source 101 rises and is similarly diffracted by the spatial modulation element 103. The diffraction angle of the diffracted light changes. For this reason, if the diffraction pattern displayed on the spatial modulation element 103 remains the same when the diffraction angle changes, a desired virtual image cannot be obtained. Therefore, in the third embodiment, the diffraction angle information acquisition unit 107 acquires information that leads to a change in the diffraction angle in the spatial modulation element 103, and based on this information, the element control unit 13a changes the calculated diffraction pattern. To do. In the present embodiment, the element control unit 13a corresponds to an example of a calculation unit, and the diffraction angle information acquisition unit 107 corresponds to an example of an acquisition unit.
Thus, according to the third embodiment, there is an effect that image quality deterioration due to a diffraction angle change due to a wavelength variation or the like of the light source 101 can be reduced. In the third embodiment, changes in the diffraction angle are handled not by movement control of the illumination optical system 102 or the reflection mirror 104 but by calculation of CGH by the element control unit 13a. Therefore, there is an effect that the illumination optical system 102 and the reflection mirror 104 can be reduced in size, simplified, reduced in cost, and extended in life. In addition, there is an effect of improving the environment adaptability such as the temperature range when the display device 1b is used.
Note that the diffraction angle information acquisition unit 107 includes any one of the temperature sensor 21, the timer 22, and the optical sensors 23 and 24, and may not include the other. Also in this form, the diffraction angle information acquisition unit 107 can acquire information that leads to a change in the diffraction angle. That is, the diffraction angle information acquisition unit 107 only needs to include at least one of the temperature sensor 21, the timer 22, and the optical sensors 23 and 24.
FIG. 12 is a block diagram showing an electrical configuration of the display device according to Embodiment 4 of the present invention. In the fourth embodiment, the same reference numerals are assigned to the same elements as in the first embodiment. Hereinafter, the fourth embodiment will be described focusing on differences from the first embodiment.
The display device 1c according to the fourth embodiment shown in FIG. 12 includes a light source control unit 11a instead of the light source control unit 11 in the display device 1 according to the first embodiment shown in FIG. The communication control unit 12a is provided. The light source 101 includes a red light source 31, a green light source 32, and a blue light source 33. Other configurations of the fourth embodiment are the same as those of the first embodiment.
The red light source 31 includes a semiconductor laser that outputs laser light having a red wavelength. The green light source 32 includes a semiconductor laser that outputs laser light having a green wavelength. The blue light source 33 includes a semiconductor laser that outputs laser light having a blue wavelength. The green light source 32 may include a semiconductor laser that outputs infrared laser light and a second harmonic generation (SHG) element that converts infrared light into green.
The light source controller 11a drives the three colors of the red light source 31, green light source 32, and blue light source 33 in a time-sharing manner. The communication control unit 12a has a wireless communication function and acquires diffraction patterns corresponding to the three colors transmitted from the external device. The communication control unit 12a controls the spatial modulation element 103 to display the acquired diffraction pattern on the spatial modulation element 103 in synchronization with the red light source 31, the green light source 32, and the blue light source 33 that are time-division driven. As a result, a color virtual image can be displayed.
In this embodiment, each of the red light source 31, the green light source 32, and the blue light source 33 has a feature that the spectrum width of the laser light output to the illumination optical system 102 is wider when the pulse is lit than when the light is constantly lit.
As described above, in the fourth embodiment, the diffraction angle required in the spatial modulation element 103 can be reduced by the convergent light illumination by the illumination optical system 102 as in the first embodiment. For this reason, the spatial modulation element 103 can tolerate a state in which the spectral width of the laser light output from the light source 101 is wider. As a result, there is an effect that color display can be suitably realized by time-division driving of the three color light sources of the red light source 31, the green light source 32, and the blue light source 33. Further, the red light source 31, the green light source 32, and the blue light source 33 used for the light source 101 have an effect of reducing the size and cost.
In the fourth embodiment, the three color light sources 31, 32, and 33 are applied to the first embodiment. However, the present invention is not limited to this and may be applied to the second embodiment. That is, in the second embodiment, the light source 101 may include the red light source 31, the green light source 32, and the blue light source 33. Then, the element control unit 13 calculates diffraction patterns corresponding to each of the three colors, and displays each diffraction pattern on the spatial modulation element 103 in synchronization with the light sources 31, 32, and 33 that are time-division driven. Also good.
FIG. 13 is a block diagram showing an electrical configuration of a display device according to Embodiment 5 of the present invention. In the fifth embodiment, the same reference numerals are assigned to the same elements as in the first embodiment. Hereinafter, the fifth embodiment will be described focusing on the differences from the first embodiment.
A display device 1d according to the fifth embodiment shown in FIG. 13 includes a communication control unit 12b in place of the communication control unit 12 in the display device 1 according to the first embodiment shown in FIG. Newly prepared. The other configuration of the fifth embodiment is the same as that of the first embodiment.
The storage unit 108 stores the myopia power of the user. The communication control unit 12b has a wireless communication function and acquires a diffraction pattern transmitted from an external device. In the acquired diffraction pattern, the communication control unit 12b changes the distance from the assumed eyeball position to the virtual image in accordance with the myopia power stored in the storage unit 108. The communication control unit 12 b controls the spatial modulation element 103 to display the changed diffraction pattern on the spatial modulation element 103.
According to the fifth embodiment, there is an effect that a simple optical system can cope with different myopia degrees for each user.
Further, according to the fifth embodiment, the myopia power corresponds to the diffraction pattern displayed not by the illumination optical system 102 but by the spatial modulation element 103, so that the illumination optical system 102 is physically driven. Thus, the size, simplification, and cost can be reduced, and the failure rate can be reduced. Also, since the myopia power of the user is stored in the storage unit 108, there is an effect that it is possible to reduce the trouble of setting the illumination optical system 102 and the spatial modulation element 103 for each use.
In the fifth embodiment, the storage unit 108 is applied to the first embodiment. However, the present invention is not limited to this and may be applied to the second embodiment. That is, in the second embodiment, the storage unit 108 may be provided. Then, the element control unit 13 calculates a diffraction pattern having a distance corresponding to the myopia power stored in the storage unit 108 as the distance from the assumed position of the eyeball to the virtual image, and uses the calculated diffraction pattern as the spatial modulation element 103. You may make it display on.
FIG. 14 is a block diagram showing an electrical configuration of the display device according to Embodiment 6 of the present invention. In the sixth embodiment, the same reference numerals are assigned to the same elements as those in the first embodiment. Hereinafter, the sixth embodiment will be described focusing on the differences from the first embodiment.
The display device 1e according to the sixth embodiment shown in FIG. 14 includes the communication control unit 12c instead of the communication control unit 12 in the display device 1 according to the first embodiment shown in FIG. Newly prepared. Other configurations of the sixth embodiment are the same as those of the first embodiment.
The wearing sensor 109 detects whether or not the display device 1e is worn by the user. As the mounting sensor 109, for example, a pressure sensor or a reflective optical sensor provided in the temple portion 111 can be used. For example, the pressure due to mounting on the head can be detected by a pressure sensor. Further, for example, reflection of light from the head can be detected by a reflection type optical sensor. Further, the mounting sensor 109 may detect an open / closed state of the temple unit 111 and the front unit 112, and may determine that the display device 1e is mounted on the user when it is open.
Based on the detection result of the mounting sensor 109, the communication control unit 12c recognizes the mounting state of the display device 1e to the user and changes the display state of the spatial modulation element 103. For example, when the mounting sensor 109 detects that the display device 1 e is mounted on the head, the communication control unit 12 c automatically starts displaying the diffraction pattern on the spatial modulation element 103. When the wearing sensor 109 detects that the display device 1e is not worn on the head, the communication control unit 12c automatically stops displaying the diffraction pattern on the spatial modulation element 103 after a predetermined time.
Further, the communication control unit 12c may display a normal image instead of displaying the diffraction pattern on the spatial modulation element 103 when the display device 1e is not attached. Accordingly, there is an effect that information can be notified to the user by displaying information such as incoming mail on the spatial modulation element 103 by the communication control unit 12c even before wearing glasses (that is, wearing the display device 1e on the head). . Alternatively, the communication control unit 12c may simultaneously display the diffraction pattern and the image on the spatial modulation element 103.
In the sixth embodiment, the mounting sensor 109 is applied to the first embodiment. However, the present invention is not limited to this and may be applied to the second embodiment. That is, in the second embodiment, the mounting sensor 109 may be provided. Then, the element control unit 13 may control the display of the spatial modulation element 103 according to the mounting state of the display device 1a on the head.
FIG. 15 is a block diagram showing an electrical configuration of the display device according to Embodiment 7 of the present invention. FIG. 16 is a diagram showing a configuration of a main part of the display device according to the seventh embodiment of the present invention. In the seventh embodiment, the same reference numerals are assigned to the same elements as those in the first embodiment. Hereinafter, the seventh embodiment will be described with a focus on differences from the first embodiment.
The display device 1f according to the seventh embodiment shown in FIG. 15 includes a communication control unit 12d instead of the communication control unit 12 in the display device 1 according to the first embodiment shown in FIG. Separately, a spatial modulation element 803 is newly provided.
The display device 1f in FIG. 16 has a glasses shape as in the first embodiment, but unlike the first embodiment, the spatial modulation element 103 is arranged not in the temple portion 111 (FIG. 1) but in the lens portion 113. Has characteristics. The display device 1 f according to the present embodiment includes another spatial modulation element 803 in addition to the spatial modulation element 103. Spatial modulation element 103 and spatial modulation element 803 are arranged on lens part 113 of front part 112 (FIG. 1) so as to overlap in the optical axis direction of the diffracted light.
The communication control unit 12d causes the spatial modulation element 803 to display a diffraction pattern (for example, an inversion pattern of the diffraction pattern displayed by the spatial modulation element 103) that cancels the phase modulation with respect to the transmitted light from the outside scene in the spatial modulation element 103. The illumination optical system 102 is disposed between the spatial modulation element 103 and the spatial modulation element 803 and illuminates the spatial modulation element 103 with laser light from the light source 101. In this embodiment, the spatial modulation element 103 and the spatial modulation element 803 are both transmissive elements.
According to the seventh embodiment, since the lens unit 113 has a display function, there is no need for a reflection mirror, and there is an effect that the display device 1f can be reduced in size and simplified. Further, according to the seventh embodiment, there is no need to arrange a spatial modulation element in the temple portion 111 (FIG. 1), and there is an effect that the temple portion 111 can be downsized. In Embodiment 7, the distance from the pupil 191 of the eyeball 190 to the spatial modulation element 103 can be reduced. Therefore, according to the seventh embodiment, there is an effect that the display device 1f can have a wider angle of view and a larger screen. In the seventh embodiment, since the diffraction pattern that cancels the phase modulation with respect to the transmitted light from the outside scene in the spatial modulation element 103 is displayed on the spatial modulation element 803, distortion of the outside scene due to the spatial modulation element 103 can be reduced. effective.
In the seventh embodiment, the spatial modulation element 803 is applied to the first embodiment. However, the present invention is not limited to this and may be applied to the second embodiment. That is, in Embodiment 2, a spatial modulation element 803 may be provided. Then, the element control unit 13 may calculate a diffraction pattern that cancels the phase modulation with respect to the transmitted light from the outside scene in the spatial modulation element 103, and may display the calculated diffraction pattern on the spatial modulation element 803.
In each of the above embodiments, the display device has a glasses shape as shown in FIG. 1, but the present invention is not limited to this, and any display device that is worn on the user's head can be used. Good.
FIG. 17 is a diagram schematically illustrating an example of a display device having a shape different from the glasses shape. A display device 1g shown in FIG. 17 includes, for example, a belt-like frame portion 200 for mounting on a user's head, a temple portion 111a connected to the frame portion 200, and a front portion connected to the temple portion 111a. 112a and a lens portion 113a formed on the front portion 112a. In the display device 1g, each member such as the spatial modulation element 103 (FIG. 1) is arranged in the same manner as in FIG. Also in the display device 1g shown in FIG. 17, the same effects as those of the above embodiments can be obtained. In the form of FIG. 17, the frame part 200 and the temple part 111a correspond to an example of a mounting part.
In addition, some of the functions of each part of the display device 1 and the like described in the above embodiments may be realized by a device different from the main body of the display device 1 and the like. In addition, functions not shown in the above embodiments may be mounted on the display device 1 or the like. Functions may be shared between the main body of the display device 1 and the like and a mobile terminal, for example, different from the display device 1 or the like. Moreover, you may share a function with the display apparatus 1 grade | etc., And a network server.
In the second embodiment, the diffraction pattern is calculated by the element control unit 13 of the display device 1a. In the first embodiment, the diffraction pattern obtained by the external device is used as the communication control unit 12 of the display device 1. Has acquired. However, the present invention is not limited to this, and a part of the calculation of the diffraction pattern may be performed outside, the communication control unit 12 may acquire the result, and the communication control unit 12 may perform the rest of the calculation of the diffraction pattern.
In each of the above embodiments, the light source 101 may be provided in an external device, and the light output from the light source 101 may be transmitted using an optical fiber. Further, the battery 106 may be provided in an external device, and the power cord may be connected to the display device 1 or the like. In addition, the display device 1 and the like may include, as other functions, a camera, various sensors such as angular velocity, temperature, and GPS, an input device such as a switch, and an output device such as a speaker.
According to each of the above embodiments, the display device 1 or the like includes the illumination optical system 102 that emits laser light illumination light, the spatial modulation element 103 that diffracts illumination light by displaying a diffraction pattern, and the user's And a temple portion 111 for mounting on the head. Further, in the display device 1 or the like, the positional relationship between the spatial modulation element 103 and the assumed eyeball position of the user is fixed in a state where the temple unit 111 is mounted on the user's head. Further, the display device 1 or the like makes the distance from the eyeball 190 to the virtual image 202 of the spatial modulation element 103 shorter than the clear vision distance, and makes the distance from the eyeball 190 to the virtual image 201 longer than the clear vision distance. As a result, the display device 1 or the like that can be enlarged can be realized by displaying the virtual image 201 far away while being small. In addition, the spatial modulation element 103 displays a diffraction pattern corresponding to the stereoscopic image, so that the stereoscopic image can be displayed to the user.
According to this configuration, the light source outputs laser light. The illumination optical system emits laser light as illumination light. The spatial modulation element diffracts the illumination light by displaying a diffraction pattern. The mounting portion is for mounting on the user's head. The positional relationship between the spatial modulation element and the assumed eyeball position assumed as the position of the user's eyeball is fixed in a state where the wearing portion is worn on the user's head. The spatial modulation element displays a diffraction pattern as a diffraction pattern that displays a virtual image to the user when the diffracted light diffracted by the diffraction pattern reaches the assumed position of the eyeball. Therefore, unlike the conventional optical enlargement method, the distance from the user's eyeball to the virtual image displayed to the user can be determined by the diffraction pattern separately from the distance from the user's eyeball to the spatial modulation element. . As a result, it is possible to provide a display device that can achieve both a reduction in size of the device and a large screen (wide angle of view) by remote display of a virtual image displayed to the user.
Further, in the display device, the spatial modulation is performed at a position where an optical axis distance from the assumed position of the eyeball to the spatial modulation element is 10 cm or less in a state where the mounting unit is mounted on the user's head. It is preferable that an element is disposed, and the spatial modulation element displays the diffraction pattern that displays the virtual image farther away than a distance from the assumed position of the eyeball to a virtual image of the spatial modulation element.
According to this configuration, the spatial modulation element is disposed at a position where the optical axis distance from the assumed position of the eyeball to the spatial modulation element is 10 cm or less in a state where the mounting portion is mounted on the user's head. The spatial modulation element displays a diffraction pattern that displays a virtual image farther away than the distance from the assumed position of the eyeball to the virtual image of the spatial modulation element. Therefore, the spatial modulation element can be disposed near the eyeball. As a result, there is an effect that it is possible to realize a small-sized display device having excellent head wearability. In addition, since the virtual image is displayed to the user by displaying the diffraction pattern on the spatial modulation element, the user's eyeball does not need to focus on the virtual image of the spatial modulation element and focuses on a virtual image farther away. You can see the image if you put them together. Therefore, there is an effect that the apparatus can be downsized by bringing the spatial modulation element closer to the eyeball without being restricted by the focus adjustment capability of the eyeball.
In addition, unlike the conventional optical enlargement method, it is not necessary to view an image on the spatial modulation element, so that the necessity for increasing the magnification is also reduced. As a result, the occurrence of aberration can be suppressed, and the image quality can be improved. Further, since the spatial modulation element can be brought close to the user's eyeball, there is also an effect that the screen can be enlarged with a wide angle of view. In addition, since the distance to the virtual image can be increased by the diffraction pattern displayed on the spatial modulation element, there is an effect that the focus adjustment fatigue of the eye can be reduced.
In the above display device, the spatial modulation element is disposed at a position where a distance from the assumed position of the eyeball to the virtual image of the spatial modulation element is shorter than a clear vision distance of 25 cm, and the spatial modulation element is assumed to be the assumed eyeball. It is preferable to display the diffraction pattern in which the distance from the position to the virtual image is longer than the clear vision distance.
According to this configuration, the spatial modulation element is disposed at a position where the distance from the assumed position of the eyeball to the virtual image of the spatial modulation element is shorter than the clear viewing distance of 25 cm. The spatial modulation element displays a diffraction pattern in which the distance from the assumed position of the eyeball to the virtual image visually recognized by the user is longer than the clear vision distance. Therefore, the spatial modulation element can be arranged at a position close to the eyeball so that the eyeball is out of focus. As a result, there is an effect that a virtual screen can be displayed at a distance where the eyeball is in focus while the main body is downsized.
In the above display device, the light source, the illumination optical system, and the spatial modulation element may further include a reflection mirror that reflects the diffracted light diffracted by the spatial modulation element toward the assumed position of the eyeball. Preferably, the reflection mirror is disposed in a cavity formed inside the mounting portion, and the reflection mirror is disposed in front of the assumed eyeball position in a state where the mounting portion is mounted on the user's head. .
According to this configuration, the reflection mirror reflects the diffracted light diffracted by the spatial modulation element toward the assumed position of the eyeball. The light source, the illumination optical system, and the spatial modulation element are arranged in a cavity formed inside the mounting portion. The reflection mirror is disposed in front of the assumed eyeball position in a state where the mounting portion is mounted on the user's head. Therefore, there is an effect that the transmission performance and reflection performance of the reflection mirror can be designed separately from the characteristics of the spatial modulation element. In addition, since the light source, the illumination optical system, and the spatial modulation element are arranged inside the mounting portion, it is possible to reduce the size other than the mounting portion and increase the degree of design freedom.
Further, in the above display device, the spatial modulation element is a reflective element, and the illumination optical system is configured such that illumination light emitted from the illumination optical system is obliquely incident on the surface of the spatial modulation element. The spatial modulation element is arranged with respect to the optical axis of the diffracted light compared to the surface of the spatial modulation element, the display surface of the virtual image displayed to the user. It is preferable to display the diffraction pattern that is nearly vertical.
According to this configuration, the spatial modulation element is a reflective element. The spatial modulation element is arranged with respect to the illumination optical system so that the illumination light emitted from the illumination optical system is incident obliquely on the surface of the spatial modulation element. The spatial modulation element displays a diffraction pattern in which a display surface of a virtual image displayed to the user is closer to a plane perpendicular to the optical axis of the diffracted light compared to the surface of the spatial modulation element. Therefore, since the spatial modulation element is a reflection type, there is an effect that the light use efficiency can be increased and power can be saved as compared with the transmission type. In addition, since the area other than the pixels of the spatial modulation element can be easily reduced, there is an effect that the image quality can be improved, and there is an effect that the element can be downsized and the dot pitch can be reduced.
Further, since the illumination light is obliquely incident on the surface of the spatial modulation element, an optical system for separating incident light and reflected light is not necessary. For this reason, there is an effect that the mounting portion can be downsized and the thickness of the mounting portion can be reduced. As a result, there is an effect that a small display device can be realized. Further, the spatial modulation element displays a diffraction pattern in which the display surface of the virtual image displayed to the user is closer to the perpendicular to the optical axis of the diffracted light than the surface of the spatial modulation element. For this reason, even if the spatial modulation element is inclined with respect to the optical axis, there is an effect that the virtual image can be brought close to vertical. Since the spatial modulation element may be disposed obliquely with respect to the illumination optical system, there is an effect that the degree of freedom in designing the mounting portion can be increased, for example, the thickness of the mounting portion can be reduced. In addition, by arranging the spatial modulation elements obliquely, the dot pitch on the basis of the optical axis is narrowed. As a result, there is an effect that the diffraction angle can be widened to widen the angle of view and increase the image quality.
In the display device described above, the mounting portion is provided with a transmission window so that the diffracted light diffracted by the spatial modulation element reaches the assumed position of the eyeball. It is preferable that the surroundings be shielded so that unnecessary diffracted light generated by external light other than the illumination light entering the spatial modulation element does not reach the assumed position of the eyeball.
According to this configuration, the mounting portion is formed with the transmission window so that the diffracted light diffracted by the spatial modulation element reaches the assumed position of the eyeball. The periphery of the transmission window in the mounting portion is shielded so that unnecessary diffracted light generated by the incidence of external light other than illumination light on the spatial modulation element does not reach the assumed position of the eyeball. Accordingly, there is an effect that unnecessary light accompanying diffraction can be reduced. Since diffraction by the spatial modulation element is performed not by the reflection mirror but by the mounting portion, there is an effect that it is not necessary to take measures against unnecessary diffracted light in the reflection mirror. Since measures against unnecessary diffracted light become easy, there is an effect that it is possible to realize a display device with less unnecessary diffracted light even in situations such as outdoors and at night when unnecessary diffracted light is generally generated.
Further, in the above display device, the diffracted light is transmitted through the reflection mirror and opposite to the assumed position of the eyeball with respect to the amount of reflected light reflected by the reflection mirror toward the assumed position of the eyeball. The amount of transmitted light output in the direction is preferably 100 times or less.
According to this configuration, the diffracted light passes through the reflecting mirror and is output in the direction opposite to the assumed eyeball position with respect to the amount of reflected light that is reflected by the reflecting mirror toward the assumed eyeball position. The amount of light is within 100 times. Therefore, there is an effect that a display device capable of displaying a virtual image by reflecting the diffracted light by the reflecting mirror while increasing the transmittance of the reflecting mirror can be realized. By setting the ratio within 100 times, the ratio of transmitted light and reflected light of diffracted light can be up to two digits, so that the amount of unnecessary transmitted light of diffracted light can be suppressed without reducing the brightness of the virtual image due to the reflected light. effective. Thereby, even when there is an eyeball other than the user or the user at a place other than the assumed position of the eyeball, there is an effect that the incident light to the eyeball can be reduced and uncomfortable feeling can be reduced. In addition, there is an effect that the output of the light source can be reduced to reduce the size and power.
Further, in the above display device, a horizontal direction in a state where the user wearing the mounting portion on the head is upright is defined as a first direction, and a direction perpendicular to the first direction is defined as a second direction. The incident angle of the diffracted light incident on the reflection mirror is defined as a first incident angle, the reflection angle of the diffracted light reflected by the reflection mirror is defined as a first reflection angle, and is incident on the reflection mirror. An incident angle of the diffracted light in the first direction is defined as a second incident angle, an incident angle of the diffracted light incident on the reflection mirror in the second direction is defined as a third incident angle, and In the reflection region, a region where the first incident angle is larger than the first reflection angle is wider than a region where the first incident angle is smaller than the first reflection angle, and the second incident angle is the third angle. The area larger than the incident angle is the second input. Corners so is wider than the area smaller than the third angle of incidence, it is preferable that the spatial modulator is arranged relative to said reflecting mirror.
According to this configuration, the horizontal direction in a state where the user who wears the mounting portion on the head stands upright is defined as the first direction. A direction perpendicular to the first direction is defined as a second direction. The incident angle of the diffracted light incident on the reflecting mirror is defined as the first incident angle. The reflection angle of the diffracted light reflected by the reflection mirror is defined as the first reflection angle. The incident angle in the first direction of the diffracted light incident on the reflecting mirror is defined as the second incident angle. The incident angle in the second direction of the diffracted light incident on the reflection mirror is defined as the third incident angle. In the reflection region of the reflection mirror, the region where the first incident angle is larger than the first reflection angle is wider than the region where the first incident angle is smaller than the first reflection angle, and the second incident angle is larger than the third incident angle. The spatial modulation element is arranged with respect to the reflection mirror so that the large region is wider than the region where the second incident angle is smaller than the third incident angle.
Therefore, there is an effect that the left and right positions of the virtual image can be brought close to the front of the user. The position of the spatial modulation element in the mounting portion can be closer to the front of the mounting portion, and as a result, there is an effect that the shape of the mounting portion with a height closer to the front reflecting mirror than to the ear of the mounting portion can be realized. . In addition, there is an effect that it is possible to realize a display device in which the diffracted light traveling from the spatial modulation element to the reflection mirror is not shielded by a part of the face around the user's eyes located between the spatial modulation element and the reflection mirror.
The display device may further include a lens unit disposed in front of the assumed eyeball position in a state where the mounting unit is mounted on the head of the user, and the reflection mirror includes the lens unit. Including the Fresnel lens bonded to the surface of the eyeball assumed position side by an adhesive, and the lens portion and the Fresnel lens bonded by the adhesive are sequentially connected from the eyeball assumed position side to the opposite side as a boundary surface. A surface on the assumed eye position side, a Fresnel lens surface, an adhesive surface, and a surface on the opposite side, the refractive index of the Fresnel lens between the surface on the assumed eye position side and the Fresnel lens surface, and A material for forming the Fresnel lens and a material for forming the adhesive so that the refractive index of the adhesive between the Fresnel lens surface and the adhesive surface is substantially equal. It is preferable to have been-option.
According to this configuration, the lens unit is disposed in front of the assumed eyeball position in a state where the mounting unit is mounted on the user's head. The Fresnel lens is bonded to the surface of the lens portion on the side where the eyeball is assumed by an adhesive. The lens part and the Fresnel lens adhered by the adhesive have, as a boundary surface, in order from the eyeball assumed position side to the opposite side, a surface on the eyeball assumed position side, a Fresnel lens surface, an adhesive surface, and an opposite surface. The Fresnel lens is formed so that the refractive index of the Fresnel lens between the surface on the assumed eye side and the Fresnel lens surface is substantially equal to the refractive index of the adhesive between the Fresnel lens surface and the adhesive surface. The material that forms the adhesive and the material that forms the adhesive are selected.
Therefore, there is an effect that the shape and inclination of the lens unit can be brought close to those of conventional glasses that do not have a function of displaying a virtual image. There is an effect that the shape of the reflection mirror can be made thin and the incident angle and reflection angle can be designed freely. The effect of realizing a display device in which diffracted light from the spatial modulation element of the mounting part is reflected as if coming from the front of the user and transmitted light from the outside passes straight and suppresses distortion of the outside scene. is there. Further, since the reflection mirror includes a Fresnel lens that is not a diffraction element, there is an effect that it is possible to avoid the influence of unnecessary diffracted light and the influence of a change in diffraction angle.
In the display device, it is preferable that the illumination optical system converges the illumination light to the assumed eyeball position.
According to this configuration, the illumination optical system converges the illumination light to the assumed eyeball position. Therefore, the required diffraction angle in the spatial modulation element can be reduced. As a result, it is possible to realize a display device that displays a virtual image with a wider angle of view and a larger screen. In addition, a simple illumination optical system that does not need to distribute parallel light as in the conventional example can be realized, and the size can be reduced. Further, as a result of the illumination light converging at the assumed eyeball position, there is an effect that the image quality and the angle of view can be increased by concentrating on the assumed eyeball position. In addition, unnecessary light other than the assumed position of the eyeball is reduced, and the required amount of light is reduced. Therefore, there is an effect that further miniaturization, higher luminance, and power saving can be realized.
Further, in the above display device, the assumed eyeball position is a center position of the user's eyeball, the width of the spatial modulation element is defined as W1, and the illumination light at the position of the user's pupil is defined. The width is defined as W2, and the width of the diffraction range at the pupil position based on the upper limit of the diffraction angle determined according to the definition of the fringes of the diffraction pattern is defined as W3, so that W3 ≦ W2 ≦ W1. It is preferable that the degree of convergence of the illumination light by the illumination optical system and the definition of the spatial modulation element are determined in advance.
According to this configuration, the assumed eyeball position is the center position of the user's eyeball. The width of the spatial modulation element is defined as W1. The width of the illumination light at the position of the user's pupil is defined as W2. The width of the diffraction range at the position of the pupil due to the upper limit of the diffraction angle determined according to the definition of the fringes of the diffraction pattern is defined as W3. The degree of convergence of the illumination light by the illumination optical system and the definition of the spatial modulation element are determined in advance so that W3 ≦ W2 ≦ W1. Therefore, it is possible to realize a display device that displays a virtual image having a wider angle of view. In addition, there is an effect that a larger spatial modulation element can be used. Further, there is an effect that the virtual image can be visually recognized even when the eyeball is rotated. There is also an effect that the image quality at the gazing point (central visual field) by the eyeball can be improved from the peripheral visual field.
Further, in the display device, the illumination optical system is configured to emit the illumination light so that a convergence center is located at a position on a line segment from the pupil center at the pupil position to the eyeball center of the user's eyeball. It is preferable to converge.
According to this configuration, the illumination optical system converges the illumination light so that the convergence center is located at a position on the line segment from the pupil center at the pupil position to the eyeball center of the user's eyeball. That is, the assumed eyeball position is located on a line segment connecting the pupil center and the eyeball center. With this configuration, when the center of convergence of the illumination light is located at the center of the pupil, there is an effect that it is possible to realize a display device that prioritizes display performance when the pupil is in front of the head. When the convergence center of the illumination light is located at the center of the eyeball, there is an effect that a display device that prioritizes display performance when the eyeball is rotated to visually recognize a virtual image can be realized. By setting the convergence center to a position on a line segment from the center of the pupil to the center of the eyeball, the balance can be freely determined.
Further, in the above display device, a horizontal direction in a state where the user wearing the mounting portion on the head is upright is defined as a first direction, and a direction perpendicular to the first direction is defined as a second direction. The illumination optical system is configured such that the convergence degree of the illumination light is different in the first direction and the second direction, and the position of the convergence center of the illumination light in the first direction is the second direction. It is preferable that the illumination light is converged so that it is closer to the center of the eyeball than the position of the convergence center.
According to this configuration, the horizontal direction in a state where the user who wears the mounting portion on the head stands upright is defined as the first direction. A direction perpendicular to the first direction is defined as a second direction. The illumination optical system is configured such that the convergence degree of the illumination light is different between the first direction and the second direction, and the position of the convergence center of the illumination light in the first direction is the center of the eyeball from the position of the convergence center in the second direction. The illumination light is converged to be close to. With this configuration, there is an effect that a display device suitable for a horizontally long virtual image can be realized.
In the display device, it is preferable that the light source outputs the laser light having a spectral width of 0.1 nm or more.
According to this configuration, the light source outputs laser light having a spectral width of 0.1 nm or more. Since the illumination light is converged by the illumination optical system, the required diffraction angle in the spatial modulation element can be reduced. As a result, there is an effect that no problem occurs even if a light source having a wider spectral width is used. As a result, the light source can be reduced in size and cost.
Further, in the above display device, the spectrum width of the laser light output from the light source is broadened when the pulse is lit compared to when the light is constantly lit, and the light source has three colors of red, green, and blue as the laser light. Preferably, laser light is output in a time-sharing manner, and the spatial modulation element displays the diffraction pattern that differs for each color in synchronization with the output of the three colors of laser light.
According to this configuration, the spectral width of the laser light output from the light source is wider when the pulse is lit than when always lit. The light source outputs laser light of three colors of red, green and blue in a time division manner as laser light. The spatial modulation element displays a different diffraction pattern for each color in synchronization with the output of the three colors of laser light. Since the illumination light is converged by the illumination optical system, the diffraction angle required in the spatial modulation element can be reduced. Therefore, a laser beam having a wider spectrum width can be used. As a result, there is an effect that color display is possible by outputting laser beams of three colors by time division driving. In addition, the light source used can be reduced in size and cost.
In the above display device, at least one of the temperature of the light source, the lighting time of the light source, the intensity of the laser light output from the light source, and the diffraction angle of the diffracted light by the spatial modulation element is diffracted. It is preferable that an acquisition unit that acquires angle information is further provided, and the spatial modulation element changes the diffraction pattern to be displayed using the diffraction angle information acquired by the acquisition unit.
According to this configuration, the acquisition unit acquires at least one of the temperature of the light source, the lighting time of the light source, the intensity of the laser light output from the light source, and the diffraction angle of the diffracted light by the spatial modulation element as diffraction angle information. To do. The spatial modulation element changes the diffraction pattern to be displayed using the diffraction angle information acquired by the acquisition unit. When the temperature of the light source rises and the wavelength of the laser light output from the light source changes, the diffraction angle of the diffracted light diffracted by the spatial modulation element changes. When the lighting time of the light source becomes longer, the temperature of the light source rises, and the wavelength of the laser light output from the light source changes, the diffraction angle similarly changes. When the intensity of the laser light output from the light source increases, the temperature of the light source rises, and the wavelength of the laser light output from the light source changes, the diffraction angle similarly changes. In contrast, the spatial modulation element changes the diffraction pattern to be displayed using the diffraction angle information acquired by the acquisition unit. For this reason, there is an effect that image quality deterioration accompanying a change in diffraction angle due to a wavelength variation of the light source can be reduced. Since the change of the diffraction angle is dealt with not by adjusting the illumination optical system but by changing the diffraction pattern, there is an effect that the illumination optical system can be reduced in size, simplified, reduced in cost and extended in life. In addition, there is an effect of improving the environment adaptability such as the temperature range when the display device is used.
The display device may further include a storage unit that stores the myopia power of the user, and the spatial modulation element has a distance from the assumed eyeball position to the virtual image that corresponds to the myopia power. It is preferable to display the diffraction pattern.
According to this configuration, the storage unit stores the myopia power of the user. The spatial modulation element displays a diffraction pattern in which the distance from the assumed position of the eyeball to the virtual image is a distance corresponding to the myopia power. Therefore, a simple illumination optical system has an effect that can cope with different myopia powers for each user.
In addition, because it corresponds to the diffraction pattern to be displayed instead of adjusting the illumination optical system for different myopia powers, the portion of the illumination optical system that is physically driven is reduced, and the illumination optical system is further reduced in size. Therefore, it is possible to simplify and reduce the cost and to reduce the failure rate. In addition, since the myopia power is stored in the storage unit, there is an effect that it is possible to reduce the trouble of setting the illumination optical system and the spatial modulation element for each user.
The display device may further include a receiving unit that receives the diffraction pattern transmitted from an external device through wireless communication, and the spatial modulation element may display the diffraction pattern received by the receiving unit. preferable.
According to this configuration, the receiving unit receives a diffraction pattern transmitted from an external device by wireless communication. The spatial modulation element displays the diffraction pattern received by the receiving unit. With this configuration, the diffraction pattern is not calculated in the main body of the display device. As a result, the display device can be reduced in size and weight. In addition, there is an effect that heat generation of a member for calculating a diffraction pattern can be reduced.
The display device preferably further includes a calculation unit that calculates a diffraction pattern corresponding to the virtual image, and the spatial modulation element displays the diffraction pattern calculated by the calculation unit.
According to this configuration, the calculation unit calculates a diffraction pattern corresponding to the virtual image. The spatial modulation element displays the diffraction pattern calculated by the calculation unit. Therefore, the virtual image can be suitably displayed to the user.
Further, in the above display device, a second lens unit provided separately from the lens unit disposed in front of the assumed eyeball position and the spatial modulation element in a state where the mounting unit is mounted on the user's head. A spatial modulation element, wherein the spatial modulation element and the second spatial modulation element are disposed in the lens unit, and the second spatial modulation element cancels phase modulation of the spatial modulation element with respect to transmitted light from outside scenes It is preferable to display a diffraction pattern.
According to this configuration, the lens unit is disposed in front of the assumed eyeball position in a state where the mounting unit is mounted on the user's head. The second spatial modulation element is provided separately from the spatial modulation element. The spatial modulation element and the second spatial modulation element are disposed in the lens unit. The second spatial modulation element displays a diffraction pattern that cancels the phase modulation of the external scene transmitted light in the spatial modulation element. Accordingly, the lens unit can have a virtual image display function. For this reason, since it is not necessary to provide a member such as a reflection mirror for directing the diffracted light from the spatial modulation element to the assumed position of the eyeball, there is an effect that the display device can be reduced in size and simplified. In addition, since the spatial modulation element is not disposed in the mounting portion, there is an effect that the mounting portion can be reduced in size. In addition, since the distance from the eyeball to the spatial modulation element can be reduced, there is an effect that a wider angle of view and a larger screen can be obtained. In addition, there is an effect that the distortion of the outside scene can be reduced by the second spatial modulation element.
In the display device according to the present invention, a spatial modulation element that diffracts the illumination light of the laser beam by displaying a diffraction pattern is arranged near the eyeball, and the diffracted light from the spatial modulation element reaches the assumed position of the eyeball, such as an HMD. It is useful as a display device. The present invention can also be applied to uses such as a display system, a display method, and a display device design method.
A light source that outputs laser light;
An illumination optical system that emits the laser light as illumination light;
A spatial modulation element that diffracts the illumination light by displaying a diffraction pattern;
A mounting part for mounting on the user's head;
A reflection mirror that reflects the diffracted light diffracted by the spatial modulation element toward the assumed position of the eyeball;
A lens unit disposed in front of the assumed position of the eyeball in a state in which the mounting unit is mounted on the head of the user;
In a state where the mounting portion is mounted on the user's head, the positional relationship between the spatial modulation element and the assumed eyeball position assumed as the position of the user's eyeball is fixed,
The spatial modulation element displays, as the diffraction pattern, a diffraction pattern that displays a virtual image to the user when the diffracted light diffracted by the diffraction pattern reaches the eyeball assumed position,
The light source, the illumination optical system, and the spatial modulation element are arranged in a cavity formed inside the mounting portion,
The reflection mirror is disposed in front of the assumed eyeball position in a state where the mounting portion is mounted on the user's head.
The spatial modulation element is a reflective element;
The spatial modulation element is arranged with respect to the illumination optical system so that the illumination light emitted from the illumination optical system is obliquely incident on the surface of the spatial modulation element,
The reflection mirror includes a Fresnel lens bonded to the surface of the lens unit on the assumed eye position side by an adhesive,
The lens part and the Fresnel lens bonded by the adhesive are, in order from the eyeball assumed position side to the opposite side as a boundary surface, the eyeball assumed position side surface, the Fresnel lens surface, the adhesive surface, and the opposite side Having a surface,
The refractive index of the Fresnel lens between the surface at the assumed position of the eyeball and the Fresnel lens surface is substantially equal to the refractive index of the adhesive between the Fresnel lens surface and the adhesive surface. Further, a material for forming the Fresnel lens and a material for forming the adhesive are selected.
The display device according to claim 1, wherein the illumination optical system converges the illumination light to the assumed position of the eyeball.
The assumed eyeball position is a position of the center of the user's eyeball,
The width of the spatial modulation element is defined as W1,
The width of the illumination light at the position of the user's pupil is defined as W2,
Defining the width of the diffraction range at the position of the pupil by the upper limit of the diffraction angle determined according to the definition of the fringes of the diffraction pattern as W3;
3. The display device according to claim 2, wherein a degree of convergence of the illumination light by the illumination optical system and a definition of the spatial modulation element are determined in advance so that W3 ≦ W2 ≦ W1. .
The illumination optical system converges the illumination light so that a convergence center is located at a position on a line segment from the pupil center at the pupil position to the eyeball center of the user's eyeball. The display device according to claim 2.
The display device according to claim 2, wherein the light source outputs the laser light having a spectral width of 0.1 nm or more.
The spectral width of the laser light output from the light source is broadened when the pulse is lit compared to when constantly lit,
The light source outputs laser light of three colors of red, green and blue in a time division manner as the laser light,
6. The display according to claim 2, wherein the spatial modulation element displays the diffraction pattern different for each color in synchronization with an output of the laser light of the three colors. apparatus.
An acquisition unit that acquires at least one of the temperature of the light source, the lighting time of the light source, the intensity of the laser light output from the light source, and the diffraction angle of the diffracted light by the spatial modulation element as diffraction angle information. In addition,
The display device according to claim 1, wherein the spatial modulation element changes the diffraction pattern to be displayed using the diffraction angle information acquired by the acquisition unit.
A receiver for receiving the diffraction pattern transmitted by wireless communication from an external device;
The display device according to claim 1, wherein the spatial modulation element displays the diffraction pattern received by the receiving unit.
An arithmetic unit that calculates a diffraction pattern corresponding to the virtual image;
The display device according to claim 1, wherein the spatial modulation element displays the diffraction pattern calculated by the calculation unit.
JP2012228697A 2011-03-25 2012-10-16 Display device Active JP5475083B2 (en)
JP2011067243 2011-03-25
JP2012228697A JP5475083B2 (en) 2011-03-25 2012-10-16 Display device
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JP2012524991A Active JP5118266B2 (en) 2011-03-25 2012-03-14 Display device
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JP2013061656A (en) 2013-04-04
JP5156876B1 (en) 2013-03-06
JP5118266B2 (en) 2013-01-16
JP5475083B2 (en) 2014-04-16
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CN102918444B (en) 2015-12-23
JP5156875B1 (en) 2013-03-06
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