JP7424188B2 - display device - Google Patents

Description

The present invention relates to a display device mounted on a vehicle such as an automobile or a motorcycle.

Conventionally, this type of display device is known, for example, as described in Patent Document 1 below. The display device described in Patent Document 1 is an in-vehicle display panel (image display device) mounted on a vehicle, and includes a rectangular liquid crystal display panel (display means) that displays predetermined information such as vehicle speed information, and a liquid crystal display panel. An image sensor (imaging means) that is capable of capturing an image of the state of a viewer viewing the image and is provided behind the liquid crystal display panel, an infrared irradiation section that irradiates infrared light toward the viewer, and the liquid crystal display panel. A rectangular light guide plate (light guide member) provided between the LCD panel and the image sensor and behind the liquid crystal display panel, and a diffusion sheet (optical member) provided between the liquid crystal display panel and the light guide member. The light guide plate and the diffusion sheet are each provided with a notch at a position corresponding to the area where the image sensor is present (for example, the center of the upper part of the light guide plate and the diffusion sheet), and a notch is provided in the light guide plate and the diffusion sheet to correspond to one side of the light guide plate. It is equipped with a light emitting element (visible light source) that emits visible light.

For example, in a situation where the infrared irradiation section is mounted on the steering column, the infrared light from the infrared irradiation section irradiates the viewer and the viewer (the viewer's face) after being irradiated. The infrared light is reflected toward the display device, passes through the liquid crystal display panel, the notch in the optical sheet, and the notch in the light guide plate, and enters the image sensor. Thereby, the image sensor can image the viewer's face illuminated by infrared light, and the state (behavior) of the viewer can be detected from the movements of the viewer's face.

International Publication No. 2018/83817

By the way, in the display device described in Patent Document 1, the outer shape of the liquid crystal display panel, the outer shape of the diffusion sheet, and the outer shape of the light guide plate are approximately the same, and the diffusion sheet and the light guide plate are provided behind the liquid crystal display panel. are stacked in this order, and the image pickup device is positioned corresponding to the notch formed at the center of the upper part of the light guide plate and the diffusion sheet.

Visible light emitted from the light emitting element enters the light guide plate, exits from the light output surface of the light guide plate facing the liquid crystal display panel, and is further uniformized by a diffusion sheet to display information on the liquid crystal display panel. However, because notches are formed at the center of the upper part of the light guide plate and the diffusion sheet, the areas of the liquid crystal display panel corresponding to the notches of the light guide plate and the diffusion sheet are in the information display area. This is a hidden area that cannot be used as a Therefore, in this case, the presence of the non-display area in a part of the liquid crystal display panel (display means) makes it impossible to secure a sufficient display area (effective display area) of the liquid crystal display panel, and in this respect, There remained room for further improvement.
Therefore, in order to deal with the above-mentioned problems, the present invention makes it possible to secure a sufficient display area of the display means even when the imaging means is arranged on the side opposite to the viewer of the display means. The purpose is to provide a display device.

The present invention provides a display means for displaying predetermined information, and a display means that is capable of capturing an image of the state of a viewer viewing the display means, and is provided on a side opposite to the viewer of the display means, which is a side opposite to the viewer side. an infrared irradiation unit that irradiates infrared light toward the viewer; a light guide member provided between the display unit and the image capture unit; and a light guide member provided between the display unit and the light guide member. a visible light source that emits visible light so as to correspond to a predetermined side surface portion of the light guiding member; the optical member has a corresponding portion corresponding to the imaging means; The corresponding portion is characterized by comprising a penetrating portion that penetrates the front and back sides of the optical member, and a non-penetrating portion that is an area excluding the penetrating portion.

The present invention also provides a display means for displaying predetermined information, and a state of a viewer who visually recognizes the display means, which is capable of capturing an image of the state of the viewer, and is provided on a non-viewer side of the display means, which is a side opposite to the viewer side. an imaging means provided, an infrared irradiation unit that irradiates infrared light toward the viewer, a light guiding member provided between the displaying means and the imaging means, and the displaying means and the light guiding member. a visible light source that emits visible light so as to correspond to a predetermined side surface portion of the light guide member; the optical member includes a substrate that can transmit the infrared light; an optical layer formed on the substrate, and a corresponding portion of the substrate corresponding to the imaging means is provided with a substrate exposed portion where the optical layer is not partially formed.

Further, the present invention is characterized in that a plurality of the penetrating portions are provided so as to be scattered throughout the optical member including the corresponding portion.

Further, in the present invention, the infrared light irradiated from the infrared irradiation section is irradiated toward the viewer, and the infrared light after irradiating the viewer is transmitted to the display means, the penetration part, and the viewer. It is characterized in that the light can enter the imaging means through the light guide member, the display means, the substrate exposed portion, the substrate, and the light guide member.

According to the present invention, it is possible to achieve the intended purpose and to secure a sufficient effective display area of the display means even when the imaging means is arranged on the opposite side of the display means to the viewer. Display devices can be provided.

FIG. 1 is a front view of a display device according to an embodiment of the present invention. AA sectional view of FIG. 1. FIG. 6 is a diagram showing the positional relationship between the optical member and the imaging means according to the same embodiment. FIG. 2 is a block diagram showing the electrical configuration of the display device according to the embodiment. The figure which shows the positional relationship of the optical member and the imaging means by the 1st modification of the same embodiment. FIG. 7 is a sectional view of a display device according to a second modification of the embodiment. The figure which shows the positional relationship of the optical member and the imaging means by the 2nd modification of the same embodiment. FIG. 7 is a front view of a display device according to a third modification of the same embodiment. BB sectional view of FIG. 8. The figure which shows the positional relationship of the optical member and the imaging means by the 3rd modification of the same embodiment.

Hereinafter, based on FIGS. 1 to 4, a case where the display device of the present invention is applied to a vehicle instrument mounted in front of the driver's seat of an automobile will be described as an example. In addition, in the following explanation, the side of the viewer who looks directly at the vehicle instrument (visual recognition) is referred to as the front side (front side), and the side opposite to the viewer side, which is opposite to the side of the viewer, is referred to as the rear side (rear side). .

1 and 2, a vehicle instrument D as a display device according to the present embodiment includes a display panel (display means) 10 that displays various vehicle information (predetermined information) such as vehicle speed information, and a display panel 10 that displays various vehicle information (predetermined information) such as vehicle speed information. A circuit board 20 located on the rear side, a light guide member 30 disposed between the display panel 10 and the circuit board 20, and illumination light (hereinafter also referred to as visible light) on one side of the light guide member 30, which will be described later. a protective member 50 that covers the front side of the display panel 10; and a camera module 60 that monitors a driver E (hereinafter also referred to as viewer E) seated in the driver's seat of the vehicle. , an optical member 70 provided between the display panel 10 and the light guide member 30, and a housing 80 that constitutes an exterior case of the vehicle instrument D.

As the display panel 10, a well-known liquid crystal display panel can be applied. In this case, the display panel 10 has a display area 11 that can display the predetermined information as an image or the like, and the predetermined information is displayed in the display area 11 configured as an effective display area of the display panel 10.

Here, a vehicle speed display section 12 that digitally displays the traveling speed of the vehicle is displayed approximately in the center of the display area 11, and various warnings to call attention to the viewer E are displayed in the upper center of the display area 11. A warning display section 13 composed of marks is displayed. Although detailed illustration is omitted here, the reference numeral 13a in FIG. 1 is a seatbelt not worn warning mark that is displayed in red when the viewer E is not wearing a seatbelt. Reference numeral 13b is a handbrake operation warning mark that is displayed in red when the viewer E is operating the handbrake.

The circuit board 20 is, for example, a hard wiring board with a wiring pattern formed on a glass epoxy base material, and controls the display of the display panel 10 and the lighting of the visible light irradiation section 40, and also controls the camera module 60 (imaging means to be described later). A control section 21 serving as a microcomputer that controls the operation of the infrared irradiation section and the infrared irradiation section) and various circuit components such as resistors and capacitors are electrically connected to the wiring pattern.

Note that the circuit board 20 is electrically connected to the display panel 10 using a flexible printed wiring board (not shown). Further, the circuit board 20 is provided with a substantially U-shaped notch 22 at the upper center of the display panel 10 so as to avoid the arrangement position of the imaging means.

The light guide member 30 is made of, for example, a transparent synthetic resin material and has a substantially flat plate shape, and is provided between the circuit board 20 (the imaging means) and the display panel 10. The light guide member 30 is located between one surface portion 31 from which visible light can be emitted, another surface portion 32 opposite to this one surface portion 31, and between one surface portion 31 and the other surface portion 32. The optical member 30 includes a side surface portion 33 that constitutes an outer circumferential surface of the optical member 30.

One surface portion 31 is configured as a smooth surface that emits visible light toward the front side, that is, the display panel 10 side. Further, the other surface portion 32 is configured as a bottom surface facing the circuit board 20 side (the imaging means side).

The visible light irradiation unit 40 can employ a plurality of chip-type light emitting diodes (visible light sources) that emit visible light of an appropriate color (for example, white visible light), and in FIG. A plurality of them are provided so as to correspond to one side surface portion 33a located on the side. This one side surface portion 33a corresponds to a predetermined side surface portion described in the claims to be described later.

The protection member 50 is a substantially flat protection panel member made of, for example, a semi-transparent (dark-colored) synthetic resin material, and is provided to cover the front side of the display panel 10 .

Further, the protective member 50 has an external shape that is one size (slightly) larger than the external shape of the display panel 10, and is located on the outside of the display panel 10 when the vehicle instrument D is viewed from the front side. It has a non-overlapping part 51 that does not overlap with 10. Note that the protective member 50 may be formed of a transparent synthetic resin material instead of a dark color, or may be bonded to the display panel 10 using a translucent adhesive. Furthermore, the outermost surface of the protection member 50 on the front side may not be a flat surface, but may be a convex or concave curved surface (curved shape).

The camera module 60 captures an image of the face of the viewer E seated in the driver's seat, and detects the state (behavior) of the viewer E from the movements of the viewer's E's face. It has an imaging means 61 that can image the state of the person E, and an infrared irradiation unit 62 that irradiates infrared light (near infrared light) toward the person E.

The imaging means 61 is a camera having sensitivity in the near-infrared region, and is arranged at a position corresponding to the upper center of the display panel 10 and on the back side of the display panel 10 . In other words, the imaging means 61 here is arranged on the back side of the display panel 10 so as to correspond to the corresponding parts provided in the warning display part 13 and the optical member 70, which will be described later.

The infrared irradiation section 62 is arranged behind the non-overlapping section 51 so as to irradiate the viewer E with infrared light. In this case, when the vehicle instrument D is viewed from the front side, the housing 80 is located directly below the non-overlapping portion 51, and the infrared ray irradiation unit 62 is located in two recesses, which will be described later, provided in the housing 80, for example. Two infrared light sources (infrared LEDs) placed (embedded) in each section can be applied.

As the optical member 70, for example, a light diffusion sheet formed in a substantially rectangular thin plate shape can be applied. Examples of the light-diffusing sheet include an optical film in which light-diffusing particles are dispersed in a light-transmitting resin film. Further, the optical member 70 is placed on the light guide member 30 so as to guide the visible light from the visible light irradiation unit 40 to the display panel 10, and the visible light emitted from the one surface 31 of the light guide member 30. It plays the role of diffusing and making it uniform.

Further, in this case, the optical member 70 has a corresponding portion 71 provided so as to correspond to the arrangement position of the imaging means 61 and the warning display portion 13. As shown in FIG. 3, the corresponding portion 71 is located at the upper center of the optical member 70, and is approximately above the display area 11 where the warning display portion 13 is displayed when the vehicle instrument D is viewed from the front side. It is provided so as to overlap with the center and the imaging means 61.

3 schematically shows the positional relationship between the imaging means 61 and the corresponding part 71 of the optical member 70. As can be seen from the description in FIG. The structure is such that the

The corresponding portion 71 is partially provided with a penetrating portion 71a by, for example, a process in which a plurality of minute pins arranged in a grid are penetrated through the corresponding portion 71. Further, the corresponding portions 71 where the penetrating portion 71a is not provided are configured as non-penetrating portions 71b as remaining portions that do not penetrate the front and back sides of the corresponding portion 71 (optical member 70). Therefore, the corresponding portion 71 here is an area where a plurality of penetrated portions 71a and non-penetrated portions 71b coexist (mix). In other words, this means that the corresponding portion 71 is composed of a penetrating portion 71a that penetrates the front and back sides of the corresponding portion 71 (optical member 70), and an unpenetrated portion 71b that is an area excluding the penetrating portion 71a. It means.

The penetrating portions 71a are scattered throughout the corresponding portion 71 as minute circular through holes penetrating the front and back sides of the corresponding portion 71 (optical member 70). That is, in this case, by performing a process of penetrating the corresponding portion 71 with a plurality of minute pins, it is possible to obtain the optical member 70 in which the corresponding portion 71 is formed with a plurality of penetrating portions 71a scattered therein.

Note that the shape of the penetrating portion 71a may be any shape other than circular, and for example, the shape of the penetrating portion 71a may be a square, a polygon, or an ellipse. Furthermore, it goes without saying that the penetrating portions 71a may be arranged regularly in the vertical and horizontal directions as shown in FIG. 3, or may be arranged in a staggered manner depending on the case.

The casing 80 is a resin instrument housing for accommodating internal components such as the display panel 10, the circuit board 20, the light guide member 30, the visible light irradiator 40, the imaging means 61, and the optical member 70. It has a substantially box shape with the panel 10 side open. The housing 80 includes a bottom wall part 81 that covers the back side of the circuit board 20, and a side wall part 82 that surrounds the sides of the display panel 10, the circuit board 20, the light guide member 30, and the like.

Here, the printed circuit board P is arranged on the inner wall surface (inner wall portion) of the one side wall portion H1 of the side wall portion 82 that faces the one side portion 33a of the light guide member 30. This printed board P is electrically connected to the circuit board 20 using a flexible printed wiring board (not shown). The visible light irradiation unit 40, which is a plurality of visible light sources, is mounted on the printed circuit board P so as to face the one side surface portion 33a.

In this case, the two recesses 82b provided in the front wall portions 82a of the pair of opposing side wall portions 82 (that is, one side wall portion H1 and the other side wall portion H2 opposing the one side wall portion H1) are Two infrared ray irradiation units 62 are respectively arranged (buried). That is, the recessed portions 82b are provided on the front wall portions 82a of the pair of opposing side wall portions 82, and the two infrared ray irradiation units 62 are arranged in these two recessed portions 82b, respectively.

Note that the infrared irradiation unit 62 is placed on a wiring board (not shown) provided at the bottom of the recess 82b. The wiring board and the circuit board 20 are electrically connected using appropriate conduction means.

The above-mentioned parts constitute the vehicle instrument D. In such a configuration, visible light emitted from the visible light irradiation section 40 is introduced into the light guide member 30 through the one side surface portion 33a. The visible light introduced into the light guide member 30 travels toward the other side surface portion 33b of the light guide member 30 opposite to the one side surface portion 33a, and is directed forward by the other surface portion 32. It is reflected toward the side and is emitted toward the front side from one surface portion 31 of the light guide member 30 . The visible light emitted from one surface portion 31 further advances to the front side and reaches the display panel 10 in a state where the light is made uniform by the optical member 70.

Here, the vehicle speed display section 12 is displayed on the display area 11 of the display panel 10 by supplying uniform visible light from the optical member 70 excluding the corresponding section 71 to the display panel 10 .

On the other hand, in the case of the present embodiment, the corresponding portion 71 of the optical member 70 is provided with an unpenetrated portion 71b as a remaining portion that does not penetrate the front and back sides of the corresponding portion 71 (optical member 70), excluding the penetrating portion 71a. Therefore, a part of the visible light emitted from one surface part 31 is supplied to the upper center of the display area 11 in a state where the light is made uniform to some extent by the non-penetrating part 71b, and thereby the vehicle speed display part The warning display section 13 is displayed in the display area 11, although the brightness is slightly lower than that of the warning display section 12. In this way, in this example, the vehicle speed display section 12 and the warning display section 13 are displayed using the entire area of the display area 11.

Further, the infrared light emitted from the infrared irradiation unit 62 passes through the non-overlapping portion 51 of the protection member 50, is emitted toward the front, and reaches the face of the viewer E. Furthermore, the infrared light after irradiating the viewer E (the face of the viewer E) is reflected in the opposite direction (to the back side), and is reflected on the display panel 10, the penetration part 71a and the light guide member 30 (more specifically, the protection The light is configured to be able to enter the imaging means 61 through the member 50, the upper center of the display panel 10, the light guiding member 30 locations corresponding to the penetrating portion 71a and the corresponding portion 71). As a result, the imaging means 61 can image the face of the viewer E illuminated by the infrared light, and acquires the reflected light reflected in the opposite direction as an image.

Next, the electrical configuration of the vehicle meter D will be described based on FIG. 4. The vehicle instrument D includes a control section 21, a display panel 10, a visible light irradiation section 40, an imaging means 61, and an infrared irradiation section 62.

The control unit 21 includes a ROM (Read Only Memory) in which an operation program of the control unit 21 is stored, a CPU (Central Processing Unit) that executes operation processing of the control unit 21 by executing the operation program, and a workpiece such as a CPU. It has a RAM (Random Access Memory) etc. used as an area.

The control unit 21 determines the state of the viewer E based on the image captured by the imaging means 61. Specifically, the control unit 21 determines whether the viewer E is drowsy or not, and whether the viewer E is driving inattentively, based on the image captured by the imaging means 61. A process for determining the state of the viewer E, such as whether or not the viewer E is present, is executed.

For example, when the control unit 21 determines that the viewer E is drowsy, the controller 21 issues a warning sound ( A process is executed to operate the speaker so that a "beep" sound effect is blown. Note that instead of blowing the warning sound, a warning message may be displayed in the display area 11 under the control of the control unit 21 to call for attention. Further, under the control of the control unit 21, the vehicle speed display unit 12 and the warning display unit 13 are displayed using the entire area of the display area 11 as described above using visible light emitted from the visible light irradiation unit 40. will be done.

As described above, the present embodiment includes the light guide member 30 provided between the display panel 10 and the imaging means 61, and the optical member 70 provided between the display panel 10 and the light guide member 30. A visible light source 40 that emits visible light is provided so as to correspond to one side surface 33 a of the optical member 30 , and the optical member 70 has a corresponding portion 71 that corresponds to the imaging means 61 . It is composed of a penetrating portion 71a that penetrates the front and back sides, and a non-penetrating portion 71b that is an area excluding the penetrating portion 71a.

Therefore, in a situation where the imaging means 61 is arranged behind the display panel 10, the infrared light after irradiating the viewer E (the face of the viewer E) is reflected in the opposite direction (toward the back side) and is protected. Since the light can enter the imaging means 61 through the member 50, the upper center of the display panel 10, the penetration part 71a of the optical member 70, and the light guide member 30, the state of the viewer E can be detected based on the image taken by the imaging means 61. can do. At the same time, a part of the visible light emitted from one surface part 31 of the light guide member 30 is made uniform to some extent by the non-penetrating part 71b provided in the corresponding part 71 coexisting with the penetrating part 71a. In this state, the information is supplied to the upper center of the display area 11, and the entire area of the display area 11 can be used as an information display area. Therefore, it is possible to provide a vehicle instrument D that can sufficiently secure the display area 11 of the display panel 10 while detecting the state of the viewer E based on the image captured by the imaging means 61.

Note that the present invention is not limited to the above-described embodiments and drawings. It is possible to make changes (including deletion of components) to the embodiments and drawings as appropriate without changing the gist of the present invention.

In the embodiment described above, a plurality of penetration parts 71a were provided in the corresponding part 71 which is a part of the optical member 70. For example, as a first modification of this embodiment, as shown in FIG. The optical member 70 may be provided in a state where it is scattered over the entire member 70, and in this case, the optical member 70 is composed of a plurality of through parts 71a and a non-penetrating part 71b as a remaining part where the through parts 71a are not formed. be done. In other words, this means that a plurality of penetrating portions 71a are provided so as to be scattered throughout the optical member 70 including the corresponding portion 71. Even in this case, any configuration can be applied to the arrangement of the penetrating portion 71a.

Further, in the optical member 70, the penetrating portion 71a provided in the corresponding portion 71 may adopt any configuration as long as the infrared light reflected to the rear side after irradiating the face of the viewer E enters the imaging means 61. For example, the number of through parts 71a through which the infrared light can pass may be one.

Furthermore, in the above-described embodiment, the corresponding portion 71 of the optical member 70 is provided with a plurality of penetrating portions 71a scattered by processing a plurality of minute pins to penetrate the corresponding portion 71. As for the configuration of the optical member 70, any configuration can be adopted as long as the infrared light reflected to the rear side after irradiating the face of the viewer E is incident on the imaging means 61. As a second modification, as shown in FIGS. 6 and 7, in place of the optical member 70 employed in the embodiment described above, it is possible to apply an optical member 90 having the same function as the optical member 70.

This optical member 90 includes a thin plate-like substrate 91 that can transmit infrared light and constitutes a base material of the optical member 90, a light diffusion layer formed on the front side (or back side) of this substrate 91, etc. A corresponding portion 91a of the substrate 91 corresponding to the imaging means 61 is provided with a substrate exposed portion 93 where the optical layer 92 is not partially formed. Note that as the optical member 90 here, a light diffusion sheet that plays a role of diffusing and uniformizing visible light can be applied.

Furthermore, the corresponding portions 91a of the substrate 91 are provided so as to correspond to the positions where the imaging means 61 and the warning display section 13 are disposed, similarly to the embodiment described above. That is, when the vehicle instrument D is viewed from the front side, the corresponding portion 91a is located at the upper center of the optical member 90 so as to overlap the upper center of the display area 11 where the warning display portion 13 is displayed and the imaging means 61. That means you are doing it.

As the optical layer 92, for example, a white light diffusing layer printed on the front side (or back side) of the substrate 91 can be applied. When the optical layer 92 is printed on the substrate 91, the substrate exposed portions 93 are configured as cut-out printing portions in which the optical layer 92 is not partially printed, and a plurality of substrate exposed portions 93 are provided so as to be scattered in the corresponding portions 91a. For example, the substrate exposed portions 93 here are approximately circular exposed portions formed at equal intervals in the horizontal and vertical directions in FIG.

In other words, in the second modified example as well, the corresponding portion 91a is in a state in which the exposed substrate portion 93 and a portion (remaining portion) of the optical layer 92 that is an area other than the exposed substrate portion 93 coexist (mix). ing.

Even in the case of the second modified example described above, the infrared light after irradiating the viewer E (the face of the viewer E) is reflected in the opposite direction (to the back side) and the display panel 10 and the substrate exposed portion 93 are reflected. , the substrate 91 and the light guide member 30 (more specifically, the protective member 50, the upper center of the display panel 10, the exposed substrate portion 93, the light guide member corresponding to the substrate 91 locations corresponding to the exposed substrate portion 93, and the corresponding portion 91a) Since the light beam can enter the imaging means 61 through 30 locations), the state of the viewer E can be detected based on the image taken by the imaging means 61. At the same time, a part of the visible light emitted from one surface 31 of the light guide member 30 is uniformized by the remaining part of the optical layer 92 provided in the corresponding part 91a coexisting with the substrate exposed part 93. The information is supplied to the upper center of the display area 11 in a state where the information has been provided to a certain extent, and the entire area of the display area 11 can be used as an area for displaying information, so that the same effects as in the embodiment described above can be obtained.

In addition, in this second modification, the shape of the substrate exposed portion 93 and the arrangement of the substrate exposed portion 93 may be changed as long as the infrared light after irradiating the face of the viewer E can enter the imaging means 61. Any configuration can be applied. The number of substrate exposed portions 93 may also be one instead of a plurality.

Further, in the embodiment described above, the digital vehicle speed display section 12 and the warning display section 13 are displayed in the display area 11, but as a third modification of the present embodiment, the vehicle speed Instead of the display section 12 and the warning display section 13, a configuration may be adopted in which a vehicle speed display section 100 consisting of an analog speedometer image is displayed in the display area 11.

The vehicle speed display section 100 as a speedometer image is an image imitating a mechanical pointer instrument, and displays vehicle speed information input through a CAN (Controller Area Network) (not shown) under the control of the control section 21, for example. It is designed to indicate a value according to the Specifically, the vehicle speed display section 100 is composed of index images 110 that are displayed in an arc-shaped arrangement, and a pointer image 120 that indicates a specific index image 110.

The index image 110 consists of a number image 111 and a scale image 112, both of which are displayed in an arcuate arrangement, and the scale image 112 is displayed outside the number image 111 so as to correspond to the number image 111. In other words, the index image 110 consisting of the number image 111 and the scale image 112 is displayed in an arc shape in red or the like along the operating range (rotation range) of the pointer image 120 and is indicated by the pointer image 120. Thereby, the viewer E can grasp the change in the traveling speed of the vehicle by comparing and interpreting the index image 110 and the guideline image 120.

The guideline image 120 indicates a specific index image 110 (a specific number image 111 and a specific scale image 112), and includes, for example, It is composed of a red pointer main body image 121 and a substantially circular pointer cap image 122 formed approximately at the center of the number image 111 and the scale image 112 (that is, the display area 11). The pointer cap image 122 is displayed in a dark color, for example, and is provided on the side opposite to the tip side of the pointer image 120, which is the scale image 112 side.

In addition, in the case of this third modification, as shown in FIG. 9, which is a cross-sectional view taken along line BB in FIG. A substantially circular hole 23 that penetrates the front and back sides of the circuit board 20 is formed in the portion, and an imaging means 61 is disposed inside the hole 23 that generally matches the shape of a corresponding portion of the optical member 70, which will be described later. .

Further, the visible light irradiation unit 40 in this third modification is provided so as to correspond to the one side surface portion 33a and the other side surface portion 33b of the light guide member 30 that faces the one side surface portion 33a, and accordingly, as described above, It is necessary to provide the printed circuit board P employed in the embodiment described above not only on the side of one side surface 33a but also on the side of the other side surface 33b. Furthermore, the corresponding portion 71 composed of the penetrating portion 71a and the non-penetrating portion 71b employed in the above-described embodiment is provided approximately at the center of the optical member 70 in this third modification, as shown in FIG. and is in a positional relationship such that it overlaps with the imaging means 61 and the pointer cap image 122 when the display panel 10 is viewed from the front side.

Even in the case of the third modified example described above, the infrared light after irradiating the face of the viewer E is reflected in the opposite direction and passes through the approximate center of the display panel 10, the penetration part 71a, and the light guide member 30. Since the light can enter the imaging means 61, the state of the viewer E can be detected based on the image taken by the imaging means 61. At the same time, a part of the visible light emitted from one surface part 31 of the light guide member 30 is made uniform to some extent by the non-penetrating part 71b provided in the corresponding part 71 coexisting with the penetrating part 71a. The speedometer image is supplied to the approximate center of the display area 11 in this state, and the entire area of the display area 11 can be used as an information display area (the speedometer image), and the same effects as in the embodiment described above can be obtained. . Note that this third modification may be combined with the above-described first modification or second modification.

Further, in the above-described embodiment and the first and third modifications, the optical member 70 is composed of one optical member 70, but the number of optical members 70 may be plural. For example, the optical member 70 is It is also called a brightness enhancement film that has the property of transmitting only the visible light that vibrates in a specific polarization direction among the incident visible light that vibrates in all directions, and reflecting the visible light that vibrates in other polarization directions. It may also be configured with a reflective polarizing sheet.

When a plurality of optical members 70 are provided in this way, it is necessary to install the plurality of optical members 70 using a well-known positioning and fixing structure so that the penetration parts 71a provided in each optical member 70 communicate with each other (overlap). be. Similarly, in the second modification described above, the number of optical members 90 may be plural. When a plurality of optical members 90 are provided, it is well known that the substrate exposed portions 93 provided in each optical member 90 overlap each other. It is necessary to install a plurality of optical members 90 using the positioning and fixing structure.

Furthermore, in the embodiment and the first to third modified examples described above, two infrared ray irradiators 62 are arranged in the recessed portions 82b of the housing 80, but the number of infrared rays irradiators 62 may be one. The number of recesses 82b may be three or more, in which case the same number of recesses 82b as the number of infrared irradiators 62 may be provided in the housing 80.

10 Display panel (display means)
13 Warning display section 20 Circuit board 21 Control section 30 Light guiding member 33 Side section 33a One side section (predetermined side section)
40 Visible light irradiation section (visible light source)
50 Protective member 60 Camera module 61 Imaging means 62 Infrared irradiation part 70, 90 Optical member 71, 91a Corresponding part 71a Penetrating part 71b Unpierced part (remaining part)
80 Housing 81 Bottom wall 82 Side wall 82b Recess 91 Substrate 92 Optical layer 93 Exposed substrate E Viewer (driver)

Claims (4)

a display means for displaying predetermined information;
an imaging means that is capable of capturing an image of the state of a viewer who visually recognizes the display means, and is provided on a side opposite to the viewer of the display means, which is a side opposite to the viewer side;
an infrared irradiation unit that irradiates infrared light toward the viewer;
a light guiding member provided between the display means and the imaging means;
an optical member provided between the display means and the light guide member,
A visible light source that emits visible light is provided so as to correspond to a predetermined side surface of the light guide member,
The optical member has a corresponding part corresponding to the imaging means,
The display device is characterized in that the corresponding portion includes a penetrating portion that penetrates the front and back sides of the optical member, and a non-penetrating portion that is an area other than the penetrating portion. a display means for displaying predetermined information;
an imaging means that is capable of capturing an image of the state of a viewer who visually recognizes the display means, and is provided on a side opposite to the viewer of the display means, which is a side opposite to the viewer side;
an infrared irradiation unit that irradiates infrared light toward the viewer;
a light guiding member provided between the display means and the imaging means;
an optical member provided between the display means and the light guide member,
A visible light source that emits visible light is provided so as to correspond to a predetermined side surface of the light guide member,
The optical member has a substrate that can transmit the infrared light, and an optical layer formed on the substrate,
A display device characterized in that a corresponding portion of the substrate corresponding to the imaging means is provided with a substrate exposed portion in which the optical layer is not partially formed. 2. The display device according to claim 1, wherein a plurality of the penetrating portions are provided so as to be scattered throughout the optical member including the corresponding portion. The infrared light emitted from the infrared irradiation unit is emitted toward the viewer,
After irradiating the viewer, the infrared light enters the imaging means through the display means, the penetration part, and the light guide member, or the display means, the substrate exposed part, the substrate, and the light guide member. The display device according to any one of claims 1 to 3, wherein the display device is enabled.

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