JP2021063934A - Head mount display and method for adjusting the same - Google Patents

Abstract

To provide a head mount display that can display a display image easily in a correct position, and a method for adjusting the head mount display.SOLUTION: A head mount display 100 according to the present embodiment includes: a reflection member located ahead of a user, the reflection member reflecting a display light forming a display image into the direction of the user; beam splitters 122L and 122R located between the reflection member and the user, the beam splitters reflecting display lights PL11 and PR11 to a reflection member and transmitting display lights PL13 and PR13 reflected by the reflection member; and light sources 501L and 501R for generating test lights PL51 and PR51 formed by the display lights PL11 and PR11 having entered the beam splitters 122L and 122R from a side opposite to a side where the display lights PL11 and PR11 enter the beam splitters 122L and 122R and reflected to the direction of the user by the beam splitters 122L and 122R.SELECTED DRAWING: Figure 3

Description

The present invention relates to a head-mounted display and a method for adjusting the head-mounted display.

Patent Document 1 discloses a see-through type head-mounted display using a half mirror. In the head-mounted display of Patent Document 1, a cross-shaped physical marker is attached on the lens surface. The position is adjusted by comparing the physical marker and the video marker. Physical markers are removable.

Japanese Unexamined Patent Publication No. 2013-186292

In such a head-mounted display, it is desired to display a virtual image at a correct position. In Patent Document 1, it is necessary to attach / detach the physical marker for adjustment every time the user changes. Therefore, there is a problem that the adjustment cannot be easily performed.

The present disclosure has been made in view of the above points, and an object of the present invention is to provide a head-mounted display capable of easily displaying a displayed image at a correct position, and a method for adjusting the head-mounted display.

The head mount display according to the present embodiment is arranged in front of the user, is arranged between a reflective member that reflects the display light forming the display image in the direction of the user, and between the reflective member and the user. A beam splitter that reflects the display light to the reflection member and transmits the display light reflected by the reflection member, and a beam splitter that is incident on the beam splitter from a side opposite to the side where the display light is incident on the beam splitter. It comprises a light source that generates test light that is reflected by the beam splitter in the direction of the user.

The method of adjusting the head mount display according to the present embodiment is arranged in front of the user, a reflective member that reflects the display light forming the display image in the direction of the user, and arranged between the reflective member and the user. A beam splitter that reflects the display light to the reflection member and transmits the display light reflected by the reflection member, and a beam splitter that is incident on the beam splitter from a side opposite to the side where the display light is incident on the beam splitter. A method of adjusting a head-mounted display including a light source that generates test light reflected by the beam splitter in the direction of the user, the step of generating display light for a test image and the test light. The user is provided with a step of adjusting the wearing state or the optical system while visually recognizing the test light superimposed on the test image.

An object of the present disclosure is to provide a head-mounted display capable of easily displaying a displayed image at a correct position, and a method for adjusting the head-mounted display.

It is a figure which shows the structure of a part of the head-mounted display which concerns on this embodiment. It is a figure which shows the functional block of the head-mounted display which concerns on this embodiment. It is a side view which shows typically the structure of the optical system of the head-mounted display which concerns on Embodiment 1. FIG. It is a top view which shows typically the structure of the optical system of the head-mounted display which concerns on Embodiment 1. FIG. It is a block diagram which shows the control part 105L. It is a figure which shows the test image. It is a figure which shows the test image and the test light in a normal position. It is a figure which shows the test image and the test light when it deviates from a normal position. It is a figure which shows the test image and the test light when it deviates from a normal position. It is a figure which shows the test image and the test light when it deviates from a normal position. It is a figure which shows the test image and the test light when it deviates from a normal position. It is a figure which shows the test image and the test light when the interpupillary distance is wide. It is a figure which shows the test image and the test light when the interpupillary distance is narrow. It is a side view which shows typically the structure of the optical system of the head-mounted display which concerns on Embodiment 2. FIG. It is a top view which shows typically the structure of the optical system of the head-mounted display which concerns on Embodiment 2. FIG. It is a block diagram which shows the control part 105L of the head-mounted display which concerns on Embodiment 3. FIG. It is a figure which shows typically the optical system and the test image of the head-mounted display which concerns on Embodiment 3. FIG. It is a figure for demonstrating the case where the interpupillary distance of a user is wide. It is a figure for demonstrating the case where the interpupillary distance of a user is narrow. It is a figure for demonstrating the state which adjusted the position of a marker when the interpupillary distance of a user is wide.

Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings. However, the present disclosure is not limited to the following embodiments. In addition, the following description and drawings have been simplified as appropriate to clarify the description.

Embodiment 1.
The head-mounted display according to the present embodiment and the display method thereof will be described with reference to the drawings. FIG. 1 is a perspective view schematically showing a part of the configuration of the head-mounted display 100. FIG. 2 is a diagram showing a part of functional blocks of the head-mounted display 100. 1 and 2 mainly show a configuration related to an image display of the head-mounted display 100. FIG. 1 shows the internal configuration of the head-mounted display 100, and in reality, each component shown in FIG. 1 may be covered with a cover or the like.

The head-mounted display 100 can be applied to various uses such as for games, entertainment, industrial use, medical use, and flight simulator use. The head-mounted display 100 is, for example, a VR (Virtual Reality) head-mounted display, an AR (Augmented Reality) head-mounted display, or an MR (Mixed Reality) head-mounted display. In the present embodiment, the head-mounted display 100 is an optical see-through type head-mounted display used for AR and MR, but it may be a non-transmissive head-mounted display.

Hereinafter, in order to clarify the explanation, the explanation will be given using the XYZ three-dimensional Cartesian coordinate system. With the user as a reference, the front-back direction (depth direction) is the Z direction, the left-right direction (horizontal direction) is the X direction, and the vertical direction (vertical direction) is the Y direction. The front direction is the + Z direction, the rear direction is the -Z direction, the right direction is the + X direction, the left direction is the -X direction, the upward direction is the + Y direction, and the downward direction is the -Y direction.

A user (not shown) is wearing the head-mounted display 100. The head-mounted display 100 includes a display element unit 101, a frame 102, an optical system 103L for the left eye, an optical system 103R for the right eye, and a control unit 105. The control unit 105 includes a control unit 105L and a control unit 105R.

The frame 102 has a goggle shape or a spectacle shape, and is attached to the user's head by a headband or the like (not shown). A display element unit 101, an optical system for the left eye 103L, an optical system for the right eye 103R, a control unit 105L, and a control unit 105R are attached to the frame 102. Although the binocular head-mounted display 100 is shown in FIG. 1, a head-mounted display having an eyeglass shape or a monocular head-mounted display may be used.

The display element unit 101 includes a left-eye display element 101L and a right-eye display element 101R. The left eye display element 101L generates a display image for the left eye. The right eye display element 101R generates a display image for the right eye. The left-eye display element 101L and the right-eye display element 101R are each provided with a flat panel display such as a liquid crystal monitor or an organic EL (Electro-Luminescence) monitor. The display element 101L for the left eye and the display element 101R for the right eye may be a display having a curved surface shape. The left-eye display element 101L and the right-eye display element 101R each include a plurality of pixels arranged in an array. Here, the array-like arrangement may be not only a two-dimensional matrix arrangement but also a pentile arrangement or the like. The left eye display element 101L is arranged on the left side (−X side) of the right eye display element 101R.

A control unit 105 is provided above the display element unit 101 (+ Y side). A video signal, a control signal, and a power source from the outside are supplied to the control unit 105. For example, a video signal or the like is input to the control unit 105 by a wired connection such as HDMI (registered trademark) or a wireless connection such as WiFi (registered trademark) or Bluetooth (registered trademark). The head-mounted display 100 may include a video generation unit (not shown) that generates a video signal, and the video signal or the like generated by the video generation unit may be input to the control unit 105.

The control unit 105L and the control unit 105R include a CPU (Central Processing Unit) and hardware resources such as a memory, and operate according to a computer program stored in the memory. Further, the control unit 105L and the control unit 105R each include a display drive circuit and the like. The control unit 105L generates a display signal for the left eye image based on the video signal, the control signal, and the like, and outputs the display signal to the left eye display element 101L. As a result, the left-eye display element 101L outputs display light for displaying the left-eye image. The control unit 105R generates a display signal for the right eye image based on the video signal, the control signal, and the like, and outputs the display signal to the right eye display element 101R. As a result, the right-eye display element 101R outputs display light for displaying the display image for the right eye. That is, the control unit 105 outputs the display signal to the display element unit 101. Further, the control unit 105L and the control unit 105R control the light sources 501L and 501R, which will be described later.

The display element unit 101 is not limited to a configuration in which the left-eye display element 101L and the right-eye display element 101R are separate display elements, and may be a single display element. A single display element may generate a display image for the left eye and a display image for the right eye. In this case, the display element unit 101 uses a part of one side of the display area of the display to generate an image for the left eye, and uses a part of the other side to generate an image for the right eye.

A part or all of the display element unit 101, the control unit 105, and the like is not limited to the configuration fixed to the frame 102, and may be provided detachably from the frame 102. For example, the display element unit 101, the control unit 105, and the like may be realized by attaching a smartphone, a tablet computer, or the like to the frame 102. In this case, an application program (application) that generates a display image for a head-mounted display may be installed in advance on a smartphone or the like.

The left eye optical system 103L guides the display light output by the left eye display element 101L to the user's left eye EL as a left eye image. The right eye optical system 103R guides the display light output by the right eye display element 101R to the user's right eye ER as a right eye image. The left eye optical system 103L is arranged on the left side (−X side) of the right eye optical system 103R. The left eye optical system 103L is arranged in front of the user's left eye EL (+ Z direction). The right eye optical system 103R is arranged in front of the user's right eye ER (+ Z direction). The user can visually recognize the virtual image of the display image generated by the display element unit 101 in the front front (+ Z direction).

The head-mounted display 100 according to the present embodiment is a semi-transmissive head-mounted display 100. Therefore, the left-eye optical system 103L and the right-eye optical system 103R are provided with a combiner described later. In the semi-transmissive head-mounted display 100, the display light from the display element section 101 and the external light are incident on the left eye EL and the right eye ER. Therefore, the user can visually recognize the superimposed image in which the display image is superimposed on the scenery in front (+ Z direction).

Hereinafter, examples of the left eye optical system 103L and the right eye optical system 103R (hereinafter, collectively referred to as an optical system) will be described. FIG. 3 is a side view schematically showing the optical system. FIG. 4 is a top view schematically showing the optical system. Since the left eye optical system 103L and the right eye optical system 103R have the same configuration, the description of the right eye optical system 103R will be omitted as appropriate.

The left eye optical system 103L includes a combiner 121L, a beam splitter 122L, and a light-shielding portion 150L. The combiner 121L, the beam splitter 122L, and the light-shielding portion 150L are fixed to the frame 102 shown in FIG.

The combiner 121L is a concave mirror, and the beam splitter 122L is a plane mirror. The combiner 121L and the beam splitter 122L are beam splitters such as a half mirror, and reflect a part of the incident light and transmit a part of the incident light. Assuming that the reflection ratio and the transmission ratio of the combiner 121L are equal, the combiner 121L transmits approximately half the amount of incident light and reflects the other half. Similarly, assuming that the reflection ratio and the transmission ratio of the beam splitter 122L are equal, the beam splitter 122L transmits approximately half the amount of incident light and reflects the other half. The combiner 121L and the beam splitter 122L may increase the reflection ratio to decrease the transmission ratio, or may decrease the reflection ratio and increase the transmission ratio.

The combiner 121L and the beam splitter 122L are arranged in front of the user's left eye EL (in the + Z direction). Further, the combiner 121L is arranged in front of the beam splitter 122L (in the + Z direction).

A left eye display element 101L is arranged above the beam splitter 122L (in the + Y direction). The left eye display element 101L emits display light PL11 for forming a display image. That is, the left eye display element 101L is arranged diagonally above the front of the left eye EL.

The light-shielding portion 150L is arranged below the beam splitter 122L (in the −Y direction). That is, the light-shielding portion 150L is arranged diagonally below the front of the left eye EL. The light-shielding portion 150L is arranged below the optical path PLL13 of the display light PL13 from the combiner 121L to the left eye EL, which will be described later. The light-shielding portion 150L is provided to block the field of view diagonally below the front. The light-shielding portion 150L is made of a black material or the like that absorbs light. Instead of the light-shielding portion 150L, a lower window for visually recognizing diagonally forward and downward may be provided.

The display light PL11 from the left eye display element 101L will be described. The display surface of the left eye display element 101L faces vertically downward (-Y direction). Therefore, the display light PL11 from the left eye display element 101L is emitted in the −Y direction.

A beam splitter 122L is inclined and arranged below the left eye display element 101L (in the −Y direction). The display light PL11 from the left eye display element 101L is incident on the beam splitter 122L. The beam splitter 122L reflects a part of the display light PL11. The display light PL11 reflected by the beam splitter 122L is referred to as the display light PL12. Further, the remaining display light PL11 transmitted through the beam splitter 122L is absorbed by the light-shielding portion 150L.

The display light PL12 reflected by the beam splitter 122L is reflected forward (+ Z direction). Then, the display light PL12 is incident on the combiner 121L. The combiner 121L reflects a part of the display light PL12 rearward (in the −Z direction). The display light PL12 reflected by the combiner 121L is referred to as the display light PL13. Further, the combiner 121L is a concave mirror, and reflects the display light PL13 so as to focus the display light PL13 toward the left eye EL. Here, all the optical paths that can be taken by the display light PL13 focused on the left eye EL are defined as the optical paths of the display light PL13. For example, in side view, the upper limit of the optical path that the display light PL13 can take is the optical path PLH13, and the lower limit of the optical path that the display light PL13 can take is the optical path PLL13. The display light PL13 reflected by the combiner 121L is incident on the beam splitter 122L. The beam splitter 122L transmits a part of the display light PL13.

The display light PL13 transmitted through the beam splitter 122L is incident on the left eye EL. In this way, the left eye optical system 103L guides the display light PL11 from the left eye display element 101L to the user's left eye EL. The optical system can display a virtual image in front of the user (+ Z direction). Further, since the concave mirror is used as the combiner 121L, the displayed image is enlarged and displayed.

Next, the external light PL21 from the front (+ Z direction) of the user will be described. A part of the external light PL21 transmits through the combiner 121L. The external light PL21 transmitted through the combiner 121L is incident on the beam splitter 122L. The beam splitter 122L transmits a part of the external light PL21. The external light PL21 transmitted through the beam splitter 122L is incident on the left eye EL.

Since the head-mounted display 100 is a transflective type, the combiner 121L synthesizes the external light PL21 from the front (+ Z direction) and the display light PL11 from the left eye display element 101L. By providing the combiner 121L in front of the user (+ Z direction), the head-mounted display 100 can be made into an optical see-through system. The display image is superimposed on the scenery in front of the user (+ Z direction). That is, the user can visually recognize the scenery on which the display image is superimposed.

Further, a light source 501L that generates the test light PL51 is provided on the upper surface of the light-shielding portion 150L. The light source 501L is, for example, an LED (Light Emitting Diode). The light source 501L is arranged directly below the beam splitter 122L. The arrangement of the light source 501L is not limited to directly below the beam splitter 122L, and may be arranged below the beam splitter 122L (in the −Y direction). The test light PL51 generated by the light source 501L is incident on the beam splitter 122L from the lower side (−Y side). The optical axis of the test light PL51 emitted from the light source 501L is parallel to the Y direction.

A part of the test light PL51 is reflected backward (in the −Z direction) by the beam splitter 122L. The remaining test light PL51 that has passed through the beam splitter 122L is absorbed by the left eye display element 101L. The test light PL51 reflected by the beam splitter 122L is used as the test light PL52. The optical axis of the test light PL52 is parallel to the Z direction. The test light PL52 is incident on the left eye EL. Therefore, the user can visually recognize the virtual image of the light source 501L in the forward direction (+ Z direction).

The test light PL51 is incident on the beam splitter 122L from the side opposite to the side where the display light PL11 is incident on the beam splitter 122L. The test light PL51 is reflected in the user direction by the beam splitter 122L. By doing so, the test light PL 52 is superimposed on the display light PL 13 and visually recognized by the user. The test light PL51 is not reflected by the combiner 121L. Therefore, the virtual image of the light source 501L is formed on the front side of the virtual image of the display image.

The configurations of the left eye optical system 103L and the right eye optical system 103R are symmetrical. Therefore, the light-shielding portion 150R is similarly provided with a light source 501R that generates the test light PR51. The test light PR51 from the light source 501R is incident on the beam splitter 122R from the lower side (−Y side). The test light PR51 is reflected by the beam splitter 122R. The test light PR52 reflected by the beam splitter 122R is incident on the right eye ER.

The light source 501L and the light source 501R are arranged apart from each other in the left-right (X direction) by a distance corresponding to a standard value of the interpupillary distance. The positions of the light source 501L and the light source 501R in the Y direction and the Z direction are the same. The test lights PL51 and PR51 are visible light. By using the same color for the test light PL51 and PR51, the user can make adjustments without any discomfort. The test lights PL51 and PR51 may have different colors.

FIG. 5 is a control block diagram showing the control unit 105L. Since the control unit 105L and the control unit 105R perform the same control, the description of the control unit 105R will be omitted in the following description. The control unit 105L includes a display image generation unit 511, a test image generation unit 512, and a switching unit 513. A switching signal from the outside is input to the switching unit 513. The switching signal is a control signal for switching the mode of the head-mounted display 100. The mode of the head-mounted display 100 includes a test mode and a normal mode.

The display image generation unit 511 generates a normal display image and outputs a display signal corresponding to the display image to the switching unit 513. The test image generation unit 512 generates a test image and outputs a test signal corresponding to the test image to the switching unit 513. The test image is an image for the user to adjust the wearing state of the head-mounted display.

A switching signal is input to the switching unit 513 to switch the mode. The switching unit 513 switches the signal output to the left eye display element 101L according to the switching signal. In the test mode for adjusting the wearing state, a test signal for a test image is supplied to the left eye display element 101L. In the test mode, the left eye display element 101L displays based on the test signal. In the normal mode, a display signal for a normal display image is supplied to the left eye display element 101L. In the normal mode, the left eye display element 101L displays based on the display signal.

For example, a switching signal is generated in response to user input. When the user operates a switch or button (not shown), a switching signal is generated. The switching signal allows the control unit 105L to switch the mode of the head-mounted display 100. By pressing a button or the like, the user can set the test mode to adjust the wearing state. Then, when the user finishes the adjustment, the user presses a button to switch to the normal mode. By doing so, the displayed image can be displayed at the correct mounting position. The switching signal is not limited to a configuration that is generated in response to user input, and a mode control unit (not shown) that generates a switching signal may be provided in the control unit 105L. For example, the mode control unit discriminates between the test mode and the normal mode based on the inputs of various sensors and the like, and inputs the discriminant result to the switching unit 513 as a switching signal.

Further, a switching signal is input to the light source 501L. In the test mode, the light source 501L is turned on to generate the test light PL51. In the test mode, the display light PL13 for the test image and the test light PL52 are superimposed. On the other hand, in the normal mode, the light source 501L is turned off and the test light PL51 is not generated. The light source 501L is switched on and off according to the switching signal.

The test image will be described with reference to FIG. FIG. 6 is a diagram showing an example of a test image. The test image for the left eye is referred to as the test image IL, and the test image for the right eye is referred to as the test image IR. The left eye display element 101L generates a test image IL based on the display signal generated by the test image generation unit 512 of the control unit 105L. The right eye display element 101R generates a test image IR based on the display signal generated by the test image generation unit 512 of the control unit 105R. The user visually recognizes the test image IL through the left eye optical system 103L and visually recognizes the test image IR via the right eye optical system 103R.

The test image IL and the test image IR each have a cross-shaped pattern. The test image IL has a vertical guideline 601L and a horizontal guideline 602L. The test image IR has a vertical guideline 601R and a horizontal guideline 602R. The guidelines 601L and 601R are straight lines along the vertical direction (Y direction), and the guidelines 602L and 602R are straight lines along the horizontal direction (X direction).

Guideline 601L and Guideline 602L intersect. The intersection of the guideline 601L and the guideline 602L is defined as the intersection 603L. Guideline 601R and Guideline 602R intersect. The intersection of the guideline 601R and the guideline 602R is defined as the intersection 603R.

FIG. 7 is a diagram schematically showing the test images IL and IR and the test light PL52 and PR52 that are visually recognized in the correct wearing state. The test light PL52 and PR52 coincide with the intersection points 603L and 603R of the guideline, respectively. That is, the test images IL and IR are formed so that the virtual images of the light sources 501L and 501R coincide with the intersections 603L and 603R in the state of being in the correct mounting position (hereinafter referred to as the normal position).

8 to 11 are diagrams schematically showing the test images IL and IR and the test light PL52 and PR52 that are visually recognized in a state deviated from the normal position. That is, FIGS. 8 to 11 show the positions of the virtual images of the light sources 501L and 501R superimposed on the test images IL and IR in the user's field of view (field of view).

FIG. 8 shows a state in which the mounting position of the head-mounted display 100 is deviated from the normal position in the upward direction (+ Y direction). In the field of view, the positions of the guidelines 602L and 602R are shifted downward (-Y direction). Therefore, the test lights PL52 and PR52 are visually recognized as being displaced upward (+ Y direction) from the intersections 603L and 603R. It is possible to recognize that the user is not in the normal position. Therefore, it is possible to encourage the user to wear it correctly.

FIG. 9 shows a state in which the mounting position of the head-mounted display 100 is deviated from the normal position in the downward direction (−Y direction). In the field of view, the positions of the guidelines 602L and 602R are shifted upward (+ Y direction). Therefore, the test lights PL52 and PR52 are visually recognized as being displaced downward (−Y direction) from the intersections 603L and 603R. It is possible to recognize that the user is not in the normal position. Therefore, it is possible to encourage the user to wear it correctly. When visually recognized as shown in FIG. 8 or 9, the user can shift the head-mounted display in the vertical direction (Y direction) to display the displayed image at the correct position.

FIG. 10 shows a state in which the mounting position of the head-mounted display 100 is deviated from the normal position in the right direction (+ X direction). In the field of view, the positions of the guidelines 601L and 601R are shifted to the left (-X direction). Therefore, the test lights PL52 and PR52 are visually recognized as being displaced to the right (+ X direction) from the intersections 603L and 603R. It is possible to recognize that the user is not in the normal position. Therefore, it is possible to encourage the user to wear it correctly.

FIG. 11 shows a state in which the mounting position of the head-mounted display 100 is deviated from the normal position in the left direction (−X direction). In the field of view, the positions of the guidelines 601L and 601R are shifted to the right (+ X direction). Therefore, the test lights PL52 and PR52 are visually recognized as being displaced to the left (−X direction) from the intersections 603L and 603R. It is possible to recognize that the user is not in the normal position. Therefore, it is possible to encourage the user to wear it correctly. When visually recognized as shown in FIG. 10 or 11, the user can shift the head-mounted display in the left-right direction (X direction) to display the displayed image at the correct position.

By superimposing the test light PL52 and PR52 on the test images IL and IR in this way, it is possible to urge the user to mount the test light PL52 and PR52 in the correct mounting position. The user may adjust the wearing state so that the test lights PL52 and PR52 are superimposed on the intersections 603L and 603R. The user can intuitively grasp the adjustment direction of the mounting position. Therefore, the user can quickly make adjustments. According to the present embodiment, it is possible to display the displayed image at the correct position with a simple configuration.

For users whose interpupillary distance between the left eye EL and the right eye ER is different from the standard value (hereinafter, standard value SPD), the test light PL52 and PR52 do not match the intersection points 603L and 603R. 12 and 13 will be used to describe a visual field image of the correct wearing position for a user having a wider interpupillary distance than the standard value SPD and a user having a narrower interpupillary distance than the standard value SPD. In the case of an adult male, the standard value SPD of the interpupillary distance is 64 mm.

FIG. 12 shows a state of wearing by a user having a wider interpupillary distance than the standard value SPD. The test light PL52 is shifted to the right (+ X direction) from the intersection 603L, and the test light PR52 is shifted to the left (−X direction) from the intersection 603R. Make the amount of left and right deviation the same. That is, a user with a wide interpupillary distance may adjust the test lights PL52 and PR52 so as to be evenly shifted inward from the intersections 603L and 603R.

FIG. 13 shows a state of wearing by a user having an interpupillary distance narrower than the standard value SPD. The test light PL52 is shifted to the left (−X direction) from the intersection 603L, and the test light PR52 is shifted to the right (+ X direction) from the intersection 603R. Make the amount of left and right deviation the same. That is, a user with a narrow interpupillary distance may adjust the test lights PL52 and PR52 so that they are evenly displaced outward from the intersections 603L and 603R.

In this way, for users whose interpupillary distance is different from the standard value SPD, the test lights PL52 and PR52 are displaced in opposite directions with respect to the intersections 603L and 603R. Therefore, the user can recognize that the interpupillary distance deviates from the standard value SPD. For users whose interpupillary distance deviates from the standard value SPD, an adjustment mechanism (not shown) may be provided to encourage adjustment of the optical system.

In the present embodiment, by superimposing the test lights PL52 and PR52 on the test images IL and IR, it is possible to recognize that the user is not wearing the test light in the normal position. Therefore, it is possible to urge the user to wear it in the normal position. The displayed image can be superimposed on the appropriate position of the scenery in front. Further, the normal mode and the test mode can be switched only by turning on and off the light sources 501L and 501R without attaching or detaching parts. Therefore, the display image can be displayed at the correct position with a simple configuration.

The display element unit 101 generates a test image IL and a test image IR having a cross pattern, but the test image IL and IR are not limited to the illustrated examples. For example, the pattern of a circle centered on the positions of the test lights PL51 and PR51 at the normal position may be displayed as the test images IL and IR. A scale indicating the amount of deviation may be added to the test image IL and the test image IR. The test image IL and the test image IR may be displayed at the same time, or may be displayed at different timings.

3 and 4 show an example of an optical system, and the optical system is not limited to the configurations of FIGS. 3 and 4. The optical system may be any one capable of guiding the display lights PL11 and PR11 from the display element unit 101 to the left eye EL and the right eye ER. For example, as the beam splitter 122L, a polarizing beam splitter that transmits or reflects light depending on the polarization state can be used. Further, the concave mirror of the combiner 121L may be a total reflection mirror instead of a semitransmissive mirror (half mirror). That is, the combiner 121L may be a reflective member. When a total reflection mirror is used as the concave mirror, the external light PL21 is not visible. Therefore, the configuration of this embodiment is also applicable to the immersive head-mounted display 100.

Further, in FIGS. 3 and 4, the beam splitter 122L and the beam splitter 122R are separately provided in the left eye optical system 103L and the right eye optical system 103R, but the left eye optical system 103L and the right eye optical system 103L are provided separately. The beam splitter may be common among the optical systems 103R. That is, one beam splitter may be used that extends from the space behind the combiner 121L (in the −Z direction) to the space behind the combiner 121R (in the −Z direction).

In the above description, the user adjusts the mounting state, but the optical system may be adjusted instead of the mounting state. For example, the inclination of the combiner 121L, 121R or the beam splitter 122L, 122R may be adjusted. Alternatively, the inclination of the left eye display element 101L or the right eye display element 101R may be adjusted. When adjusting the optical system, the head-mounted display 100 may be provided with a knob or the like for changing the inclination.

The adjustment method according to the present embodiment is a step of generating the display optics PL11 and PR11 for the test image and the test optics PL51 and PR51, and the user visually recognizing the test optics PL52 and PR52 superimposed on the test image. It has a step of adjusting the mounting state or the optical system. As a result, the display position can be easily adjusted.

Embodiment 2.
The head-mounted display 100 according to the second embodiment will be described with reference to FIGS. 14 and 15. FIG. 14 is a side view showing the configuration of the head-mounted display 100, and FIG. 15 is a top view. In the second embodiment, lower windows 130L and 130R are provided to obtain a field of view obliquely downward in the front direction. Since the basic configuration and control of the head-mounted display 100 are the same as those in the first embodiment, the description thereof will be omitted. Further, also in the present embodiment, since the configurations of the left eye optical system 103L and the right eye optical system 103R are the same, the description of the right eye optical system 103R will be omitted as appropriate.

The lower window 130L is arranged below the beam splitter 122L (in the −Y direction). That is, the lower window 130L is arranged diagonally below the front of the left eye EL. The lower window 130L is provided to obtain a field of view diagonally forward and downward. The user can visually recognize the front diagonally lower part through the lower window 130L. The user can obtain a downward view according to the size of the area of the lower window 130L. The lower window 130L is arranged parallel to the XZ plane. Of course, the angle at which the lower window 130L is installed is not particularly limited. For example, the lower window 130L may be arranged with an inclination such that the −Z side is high and the + Z side is low. The lower window 130L is arranged below the optical path PLL13 of the display light PL13 from the combiner 121L to the left eye EL.

A louver or the like can be used as the lower window 130L. For example, the louver is installed so as to block external light from directly below the beam splitter 122L and transmit external light from diagonally below the front. By using a louver as the lower window 130L, it is possible to secure a diagonally downward view. Further, instead of the louver, a polarizing plate or a translucent plate may be used as the lower window 130L.

In the present embodiment, the light source 501L is arranged outside the lower window 130L in the top view so as not to obstruct the view obliquely downward. That is, the light source 501L is arranged at a position off the optical path between the lower window 130L and the beam splitter 122L. The light source 501L is arranged on the left side (−X side) of the lower window 130L. An optical element 502L is arranged on the upper surface of the lower window 130L. The light source 501R is arranged on the right side (+ X side) of the lower window 130R. An optical element 502R is arranged in the lower window 130R.

The light source 501L emits the test light PL51 toward the optical element 502L. The light source 501R emits the test light PR51 toward the optical element 502R. As the optical elements 502L and 502R, minute reflective materials such as glass beads and aluminum foil can be used. Optical elements 502L and 502R are provided on the lower windows 130L and 130R, respectively.

The test light PL51 from the light source 501L is incident on the optical element 502L from the left direction. The optical element 502L is a reflective material and reflects the test light PL51 in the upward direction (+ Y direction). The test light PL51 reflected by the optical element 502L is reflected by the beam splitter 122L. The test light PL52 reflected by the beam splitter 122L is incident on the left eye EL. The optical element 502L may be any as long as it can reflect the test light PL51 toward the beam splitter 122L. For example, the optical element 502L may be a light guide member such as an optical fiber.

The test light PR51 from the light source 501R is incident on the optical element 502R from the right direction. The optical element 502R is a reflective material similar to the optical element 502L, and reflects the test light PR51 in the upward direction (+ Y direction). The test light PR51 reflected by the optical element 502R is reflected by the beam splitter 122R. The test light PR52 reflected by the beam splitter 122R is incident on the right eye ER. The optical element 502R may be any as long as it can reflect the test light PR51 toward the beam splitter 122R. For example, the optical element 502R may be a light guide member such as an optical fiber.

By doing so, even the head-mounted display 100 having the lower windows 130L and 130R can prompt the user to adjust the mounting position. Further, since a component smaller than the light source 501L can be used as the optical element 502L, the region obstructing the view of the lower window 130L can be reduced. Further, it is possible to prevent the wiring of the light source 501L from obstructing the field of view. Therefore, a wider field of view can be secured.

The arrangement of the light sources 501L and 501R is not limited to the illustrated configuration. The light source 501L may be arranged between the lower window 130L and the beam splitter 122L and at a position outside the optical path of the display light PL13 from the combiner 121L to the left eye EL. The light source 501R may be arranged between the lower window 130R and the beam splitter 122R and at a position outside the optical path of the display light PR13 from the combiner 121R to the right eye ER. The light sources 501L and 501R may emit the test lights PL51 and PR51 to the optical elements 502L and 502R from the front-rear direction (Z direction) or the oblique direction of the lower window 130L. Instead of the lower windows 130L and 130R, light-shielding portions 150L and 150R may be provided as in the first embodiment. That is, it is sufficient that the bottom portion of the display light PL13 and PR13 is provided below the optical paths PLL13 and PRL13.

Embodiment 3.
As described in the first embodiment, the positions of the virtual images of the light sources 501L and 501R in the test images IL and IR change according to the interpupillary distance of the user. Therefore, the user can recognize whether or not the interpupillary distance of the user deviates from the standard value. In the third embodiment, when the user's interpupillary distance deviates from the standard value, the interpupillary distance adjustment mode is set. In the adjustment mode, the interpupillary distance is measured and the measured interpupillary distance is reflected in the generation of the display image.

Specifically, in the present embodiment, the control unit 105 controls based on the interpupillary distance of the user. The head-mounted display 100 of the third embodiment will be described with reference to FIGS. 16 and 17. FIG. 16 is a block diagram showing the configuration of the control unit 105L. FIG. 17 is a schematic diagram for explaining an optical system and a test image. The mode of the head-mounted display 100 according to the third embodiment includes an adjustment mode. Since the basic configuration and control are the same as those in the first and second embodiments, the description thereof will be omitted.

An adjustment signal from the outside is input to the test image generation unit 512. It switches to the adjustment mode according to the adjustment signal. For example, when the user's interpupillary distance is different from the standard value SPD, the user presses an adjustment button (not shown). As a result, an adjustment signal for switching to the adjustment mode is generated, and the head-mounted display 100 switches to the adjustment mode. The adjustment signal may include a signal for instructing the measurement of the interpupillary distance in addition to the signal for switching to the adjustment mode. The adjustment signal is not limited to the configuration generated in response to the user input, and the control unit 105L may be provided with an adjustment control unit (not shown) that generates the adjustment signal. For example, when the adjustment control unit detects that the interpupillary distance of the user is different from the standard value SPD based on the input of various sensors or the like, the adjustment control unit inputs the adjustment signal to the test image generation unit 512.

In the adjustment mode, the display light PL13 and the test light PL52 reach the left eye EL as in the test mode. The test image generation unit 512 generates a test image in response to the adjustment signal. In order to measure the interpupillary distance, the test image generation unit 512 changes the test image based on the adjustment signal. If the mode of the head-mounted display 100 is the normal mode when the mode is switched to the adjustment mode, the control unit 105 turns on the light sources 501L and 501R.

In FIG. 17, virtual images of the light sources 501L and 501R are shown as virtual images V501L and V501R. As shown in FIG. 17, the distance DS between the light sources between the virtual image V501L and the virtual image V501R coincides with the standard value SPD of the interpupillary distance. The virtual images V501L and V501R are formed in front of the user.

The test image IL has a circular marker 611L. The test image IR has a circular marker 611R. The test image generation unit 512 displays the test images IL and IR so that the user recognizes that the circular markers 611L and 611R are localized at infinity, respectively. Specifically, the test image generation unit 512 displays the test images IL and IR so that the distance between the circular markers 611L and 611R is equal to the standard value SPD in the virtual image of the test images IL and IR. The marker 611L and the marker 611R have the same size and the same color. The virtual images of the test images IL and IR are visually recognized in front of the combiners 121L and 121R (in the + Z direction).

The distance between the circular markers 611L and 611R in the virtual images of the test images IL and IR and the distance DS between the light sources between the virtual images V501L and V501R of the light sources 501L and 501R are equal to the standard value SPD, respectively. Therefore, the virtual images of the test images IL and IR and the virtual images V501L and V501R of the light sources 501L and 501R are recognized by the user so as to be localized at infinity, respectively. Therefore, when the user sees it with both eyes, it is visually recognized as a binocular image IC in which the test images IL and IR overlap. In the binocular image IC, a circular pattern 620 in which two markers 611L and 611R are overlapped is visually recognized. When the user tries to match the line of sight with the virtual images of the test image IL and the test image IR, the two markers 611L and 611R overlap and are displayed as one circular pattern 620. Further, when the distance DS between the light sources is the same as the standard value SPD, the virtual images V501L and V501R coincide with the center of the circular pattern 620.

18 and 19 show a case where the user's interpupillary distance UPD and the light source distance DS are different. FIG. 18 shows a case where the user's interpupillary distance UPD is wider than the light source distance DS. FIG. 19 shows a case where the user's interpupillary distance UPD is narrower than the light source distance DS. The interpupillary distance DS is consistent with the standard value SPD of the interpupillary distance. Therefore, FIG. 18 shows a case where the user's interpupillary distance UPD is larger than the standard value SPD. FIG. 19 shows a case where the user's interpupillary distance UPD is smaller than the standard value SPD.

As shown in FIGS. 18 and 19, in the binocular image IC, the virtual images V501L and V501R deviate from the center of the circular pattern 620. For example, when the user's interpupillary distance UPD is wider than the standard value SPD, the virtual image V501L shifts to the right side (+ X side) of the center of the circular pattern 620, and the virtual image V501R shifts to the left side (-X side) of the center of the circular pattern 620. It shifts. When the user's interpupillary distance UPD is narrower than the standard value SPD, the virtual image V501R shifts to the right side (+ X side) of the center of the circular pattern 620, and the virtual image V501L shifts to the left side (-X side) of the center of the circular pattern 620. In the binocular image ICs shown in FIGS. 18 and 19, the virtual images V501L and V501R are contained inside the circular pattern 620, respectively, which is an example. In the binocular image IC, the virtual images V501L and V501R may protrude outside the circular pattern 620, such as when the difference between the interpupillary distance UPD and the standard value SPD is large.

When the interpupillary distance UPD of the user is different from the standard value SPD, the user visually recognizes the binocular image IC as shown in FIGS. 18 and 19. In FIGS. 18 and 19, the virtual images V501L and V501R do not overlap in the binocular image IC. When a binocular image IC in which the virtual images V501L and V501R do not match is visually recognized at the center of the circular pattern 620, the user presses a position adjustment start button (not shown). As a result, an adjustment signal for instructing the start of position adjustment for measuring the interpupillary distance is generated. When the position adjustment start button is pressed, the test image generation unit 512 gradually changes the positions of the markers 611L and 611R.

Specifically, when the position adjustment start button is pressed, the test image generation unit 512 generates the test images IL and IR so as to shift the positions of the markers 611L and 611R in the test images IL and IR to the left and right. The test image generation unit 512 shifts the positions of the markers 611L and 611R by the same distance and in opposite directions. For example, the marker 611L is gradually shifted to the left (−X direction), and the marker 611R is shifted to the right (+ X direction) by the same amount of deviation as the marker 611L. This adjustment direction is defined as the first position adjustment direction. Alternatively, the marker 611R is gradually shifted to the left (−X direction), and the marker 611L is shifted to the right (+ X direction) by the same amount of deviation as the marker 611R. This adjustment direction is defined as the second position adjustment direction.

When the position adjustment start button is pressed, the test image generation unit 512 arbitrarily shifts the positions of the markers 611L and 611R in the first position adjustment direction or the second position adjustment direction. You can decide. The test image generation unit 512 may switch between the first and second position adjustment directions each time the position adjustment start button is pressed.

By doing so, the virtual images V501L and V501R can be aligned with the center of the circular pattern 620 as in the binocular image IC of FIG. FIG. 20 shows markers 611L'and 611R' offset in position when the user's interpupillary distance UPD is wider than the interpupillary distance DS. That is, from the position of FIG. 18, the marker 611R is shifted to the left (−X direction) to be the marker 611R ′, and the marker 611L is shifted to the right (+ X direction) to be the marker 611L ′. The user presses a position adjustment stop button (not shown) at the timing when the virtual images V501L and V501R coincide with the center of the circular pattern 620. As a result, an adjustment signal for instructing the stop of the position adjustment for measuring the interpupillary distance is generated. When the position adjustment stop button is pressed, the test image generation unit 512 stops the change at the positions of the markers 611L'and 611R'. This makes it possible to measure the user's interpupillary distance UPD based on the deviation amount DY between the markers 611L and 611R and the markers 611L'and 611R'.

That is, the deviation amount DY between the markers 611L and 611R at the timing when the user presses the position adjustment start button and the markers 611L'and 611R'at the timing when the position adjustment stop button is pressed is the standard value of the interpupillary distance UPD of the user. Corresponds to the amount of deviation from SPD. The control unit 105 obtains the deviation amount DY between the markers 611L and 611R in the state of FIG. 18 and the markers 611L'and 611R'in the state of FIG. 20, and converts the deviation amount DY into a distance.

This makes it possible to measure the user's interpupillary distance UPD. The control unit 105 stores the measured user's interpupillary distance UPD in a memory or the like. The display image generation unit 511 provided in the control unit 105 reflects the user's interpupillary distance UPD in the generation of the display image. That is, the control unit 105 generates the left and right display images based on the user's interpupillary distance UPD. Thereby, higher display quality can be obtained.

The shapes of the markers 611L and 611R are not limited to a circular shape. Markers such as crosses, quadrangles, and polygons may be used. The markers 611L and 611R may have shapes that allow the user to recognize the overlap and the center. The interpupillary distance DS may deviate from the standard value SPD of the interpupillary distance.

By making the test light PL51 and the test light PR51 the same color, the user can visually recognize the virtual image without discomfort. The test light PL51 and the test light PR51 may have different colors. For example, the test light PL51 is used as the first color, and the test light PR51 is used as the second color. By determining which of the virtual images V501L and V501R deviated from the center is the first color in the binocular image IC, it is possible to recognize whether the interpupillary distance is narrower or wider than the standard value SPD. Thereby, the direction in which the markers 611L and 611R are shifted can be determined. In addition, Embodiments 1 to 3 can be combined appropriately. For example, in the control of the third embodiment, the optical system of the second embodiment may be used.

Although the invention made by the present inventor has been specifically described above based on the embodiment, the present invention is not limited to the above embodiment and can be variously modified without departing from the gist thereof. Needless to say. It is also possible to appropriately combine two or more of the above embodiments.

EL Left eye ER Right eye 100 Head mount display 101 Display element 101L Left eye display element 101R Right eye display element 102 frame 103L Left eye optical system 103R Right eye optical system 121L, 121R Combiner 122L, 122R Beam splitter 130L , 130R Lower window 150L, 150R Light-shielding part PL11, PL12, PR11, PR12 Display light PL21, PR21 External light PL51, PR51 Test light 501L, 501R Light source 502L, 502R Optical element 511 Display image generation part 512 Test image generation part 513 Switching part 601L, 601R, 602L, 602R Guideline 611L, 611R Marker 620 Circular pattern

Claims (6)

A reflective member that is placed in front of the user and reflects the display light forming the display image in the direction of the user.
A beam splitter arranged between the reflective member and the user, which reflects the display light to the reflective member and transmits the display light reflected by the reflective member.
A head-mounted display comprising a light source in which the display light is incident on the beam splitter from a side opposite to the side incident on the beam splitter to generate test light reflected by the beam splitter in the direction of the user. Further provided with a bottom located below the optical path of the indicator light reflected by the reflective member and directed towards the user's eye.
In top view, the light source is located outside the bottom.
An optical element is provided on the upper surface of the bottom.
The head-mounted display according to claim 1, wherein the optical element reflects the test light incident from the light source toward the beam splitter. A display element for displaying the display image and a control unit for displaying the test image on the display element are provided.
The control unit switches between the normal mode and the test mode according to a switching signal for switching between the normal mode and the test mode.
In the normal mode, the control unit displays the normal display image and displays the normal display image.
In the test mode, the control unit displays the test image and displays the test image.
In the normal mode, the light source turns off the test light,
The head-mounted display according to any one of claims 1 to 2, wherein the light source turns on a test light in the test mode. The control unit generates a test image for the left eye and a test image for the right eye, respectively.
The left eye test image and the right eye test image each contain a marker.
The head-mounted display according to claim 3, wherein the distance between the pupils of the user is measured by shifting the positions of the markers in the test image for the left eye and the test image for the right eye in the left-right direction. The head-mounted display according to claim 4, wherein the control unit forms the display image based on the interpupillary distance. A reflective member that is placed in front of the user and reflects the display light forming the display image in the direction of the user.
A beam splitter arranged between the reflective member and the user, which reflects the display light to the reflective member and transmits the display light reflected by the reflective member.
Adjustment in a head-mounted display including a light source in which the display light is incident on the beam splitter from a side opposite to the side incident on the beam splitter to generate test light reflected by the beam splitter in the direction of the user. It's a method
A step of generating the display light forming the test image and the test light, and
An adjustment method comprising: a step of adjusting a mounting state or an optical system while the user visually recognizes a test light superimposed on the test image.

Images