JP6380155B2 - Display device and display control method - Google Patents

Description

  The present invention relates to a display device and a display control method for displaying information to a driver.

  Many vehicles are equipped with a display (hereinafter referred to as a display device) for displaying images, and provide various types of information to the driver using a car navigation system or the like. The display device emits light toward the front of the display device from a light source (such as a liquid crystal display surface) that emits light for displaying an image, thereby displaying information to the driver watching the display device. (For example, Patent Document 1).

Japanese Patent Laid-Open No. 11-42971

  However, the conventional display device is based on the premise that the light from the light source is emitted toward the front of the display device, and the display direction is uniform. For example, a driver looking at the traveling direction of the vehicle In addition, there is a problem that even when trying to notify by displaying specific information on the display device, it may not be noticed.

  The present invention has been made in view of the above-described problems of the prior art, and an object of the present invention is to provide a technique that enables a display that is easy for the driver to notice by increasing variations in the display direction of the display device.

  In order to solve the above-described problems, a display device of the present invention includes a light source that emits light for displaying an image toward the front side of the display device, and a front body provided on the front surface of the display device. The center of the front body is provided with a central portion that emits the light of the light source toward the front of the display device, and the light of the light source is inclined outward from the front along the outer periphery of the central portion on the outer edge of the front body. Provide an outer edge to discharge. If it carries out like this, as the direction which discharge | releases light from a display apparatus, not only the front of a display apparatus but the direction inclined to the outer side of the center part with respect to the light aimed at this front can be added. For example, even when the driver looks at the traveling direction of the vehicle, if the light is emitted not only in front of the display device but also in a direction inclined outward, the driver can easily notice the display. The light emitted to be tilted outward is emitted from the same light source as the light emitted toward the front, and therefore it is not necessary to provide a new light source in order to add a display direction.

In order to solve the above-described problem, the display device and the display control method of the present invention include a display control unit that controls a light source to display an image, and obtains specific information notified to the driver. by controlling the area corresponding to the outer edge of, by moving the part that emits light from the outer edge, it executes Viewing set according to particular information. For example, while displaying information related to car navigation etc. at the center, and when notifying the driver of information other than this, display in a predetermined manner is performed at the outer edge. When displayed at the outer edge, light in a display direction different from the display direction of information related to car navigation etc. enters the driver's field of view. The driver can be surely noticed. In addition, since the display of the predetermined mode is set according to the specific information, the specific information is transmitted only by the driver noticing that the display of the predetermined mode is executed.

It is explanatory drawing which shows the external appearance of the display apparatus of a present Example, and the installation position in the vehicle. It is an expanded sectional view of the upper part of the display apparatus 10 cut | disconnected by the AA line of FIG. It is a front view of the display apparatus 10 which illustrated the display mode using the light discharge | released from the outer edge part 13. FIG. 5 is a flowchart of outer edge display processing executed by a display control unit 16. It is sectional drawing which cut | disconnected the upper part of the display apparatus 10 of the modification by the AA line of FIG.

Hereinafter, examples will be described in order to clarify the contents of the present invention described above.
A-1. Apparatus configuration of this embodiment:
FIG. 1 shows the appearance and installation position of the display device 10 mounted on the vehicle 1. The display device 10 is a device for displaying information about various functions mounted on a vehicle as an image, and can be used as, for example, a car navigation display or a back monitor. As shown in the drawing, the display device 10 is installed on the upper surface of the dashboard at a position on the left side when viewed from the driver seat of the right handle, and the front surface for displaying an image is directed to the rear of the vehicle 1. The term “image” here refers to the visual information displayed on the display as a whole, and is not limited to photographs, paintings, and figures, but also includes characters and the like.

  The shape of the front surface of the display device 10 is a substantially rectangular shape having upper, lower, and left and right sides, and the upper left and right corners are rounded in an arc shape, and the lower left and right corners intersect at right angles. Shape. The glass plate 11 covering the front surface of the display device 10 is divided into a central portion 12 that occupies most of the central region of the glass plate 11 and an outer edge portion 13 that surrounds the outer periphery of the central portion 12. In FIG. 1, in order to clarify the difference between the central portion 12 and the outer edge portion 13, the width of the outer edge portion 13 occupied in the glass plate 11 is shown larger than the actual width.

  2 is an enlarged cross-sectional view of the display device 10 taken along line AA in FIG. In addition, in order to avoid illustration becoming complicated, the hatching showing the cross section of the glass plate 11 is abbreviate | omitted. As shown in FIG. 2, a liquid crystal display 14 is provided behind the glass plate 11, and a frame 15 of the display device 10 is provided so as to surround the outer periphery of the liquid crystal display 14. In addition, although there are various circuits and the rear surface of the display device 10 behind the liquid crystal display 14, illustration is omitted.

  Here, the surface of the glass plate 11 on the side in contact with the liquid crystal display 14 is the back surface, and the surface of the glass plate 11 on the side opposite to the liquid crystal display 14 is the outer surface. Of the glass plate 11, the outer surface of the central portion 12 is directed forward, while the outer surface of the outer edge portion 13 is directed obliquely upward and the outer surface of the outer edge portion 13 is centered. Inclined with respect to 12 outer surfaces.

  The display device 10 also includes a display control unit 16 that controls display on the liquid crystal display 14. The display control unit 16 can be realized as a computer program executed by the CPU, can be realized as an electronic circuit including an LSI and a memory, or can be realized by combining them.

  A thin line arrow in FIG. 2 schematically represents the state of light emitted from the liquid crystal display 14 and incident on each of the central portion 12 and the outer edge portion 13. The light emitted from an arbitrary point on the display surface of the liquid crystal display 14 includes light in various traveling directions, but in FIG. 2, three directions are representatively shown. The light emitted in these three directions travels straight inside the glass plate 11 (the central portion 12 or the outer edge portion 13) and enters the outer surface of the glass plate 11 (the boundary surface between the glass plate 11 and outside air). To do.

First, the traveling direction of light incident on the outer surface of the central portion 12 of the glass plate 11 will be described. Of the light incident on the outer surface of the central portion 12, the incident angle (the angle formed by the normal direction of the outer surface and the incident direction) is larger than a predetermined angle (the obliquely upward direction among the three directions shown in the figure) And light obliquely downward) are reflected by the outer surface of the central portion 12 and are not emitted outside. This predetermined angle is called a critical angle, and is an angle determined from the refractive index of the glass plate 11 and the refractive index of air.
On the other hand, light whose incident angle is smaller than the critical angle (light traveling forward among the light in the three directions shown) is emitted outside without being reflected by the outer surface of the central portion 12. This is the same for light incident on any point on the outer surface of the central portion 12, and the direction in which light is emitted from the outer surface of the central portion 12 is determined by the two white arrows in FIG. Of these, as indicated by the lower arrow, the front of the display device 10 is mainly used.

Then, the advancing direction of the light which injects into the outer surface of the outer edge part 13 among the glass plates 11 is demonstrated. Of the light in the three directions shown in the figure, the light traveling toward the front of the display device 10 is emitted from the central portion 12, but the incident angle with respect to the outer surface of the outer edge portion 13 is larger than the critical angle. It becomes larger and is reflected and is not emitted outside.
On the other hand, the light traveling obliquely upward is not emitted outside from the central portion 12, but is incident on the outer surface of the outer edge portion 13 with an incident angle smaller than the critical angle and is emitted outside without being reflected. Accordingly, the direction in which light is emitted from the outer surface of the outer edge portion 13 is mainly a direction obliquely upward from the front of the display device 10, as indicated by the upper arrow of the two white arrows in FIG. It becomes.

  As described above, since light having an incident angle larger than the critical angle is not emitted from the outer surface, the traveling direction of the light emitted from the outer surface is mainly the normal direction of the outer surface. And since the direction of an outer surface differs in the center part 12 and the outer edge part 13, the direction of the light discharge | released from both also differs from each other. In this way, in the display device 10 of the present embodiment, even if the light is emitted from the liquid crystal display 14 in the same direction, the light passing through the central portion 12 is emitted forward and passes through the outer edge portion 13. The display direction variation can be increased such that the light to be emitted is emitted obliquely upward from the front.

  The conventional display is based on the premise that light for displaying an image is emitted forward. In order to emit light in a direction different from the front, for example, an LED lamp or the like facing the direction is separately provided around the display. It is possible. However, according to the display device 10 of the present embodiment, the light source of light emitted from the outer edge portion 13 is the liquid crystal display 14 in the same manner as the light source of light emitted from the central portion 12, and therefore it is necessary to provide a separate LED lamp. Absent. Further, when a separate LED lamp is provided, the color of the emitted light is determined by the color of the LED lamp. However, in the display device 10 of this embodiment, the liquid crystal display 14 capable of color display is used as the light source. The light emitted from the outer edge portion 13 can also be displayed by changing the color in the same manner as the display of the central portion 12.

The glass plate 11 corresponds to the “front body” of the present invention, and the liquid crystal display 14 corresponds to the “light source” of the present invention. The “front body” may be a transparent member that allows light to pass therethrough, and the material is not limited to glass but may be resin or the like. The central portion 12 and the outer edge portion 13 of the glass plate 11 may be provided integrally or separately.
Further, the “light source” may be any display that can emit light for displaying an image, and is not limited to a liquid crystal display, and an organic EL display or the like can be used. The liquid crystal display generally includes a glass substrate as a component, and the glass substrate may be the glass plate 11 of the present embodiment, or the glass plate 11 may be provided separately from the glass substrate.

  Up to this point, the outer edge portion 13 has been described with reference to the upper part of the display device 10 with reference to FIG. 2, but as shown in FIG. It is also provided at the side and the lower part and surrounds the entire circumference of the display device 10. And, as the outer surface of the upper outer edge portion 13 is upward (see FIG. 2), the outer surface of the outer edge portion 13 on the left side is facing left, and the outer surface of the outer edge portion 13 on the right side is facing right. In other words, the outer surface of the lower outer edge portion 13 faces downward, such that the outer surface of the outer edge portion 13 faces outward rather than forward.

Similarly, the outer surfaces of the left and upper connecting portions of the outer edge portion 13 and the outer surfaces of the right and upper connecting portions are also outwardly facing in a similar manner to the curved surface of the conical side surface along the arc-shaped outer peripheral shape. It has become. As described above, the outer edge portion 13 is not limited to a flat surface but can be formed as a curved surface. In this embodiment, the outer edge portion 13 is provided on the entire outer periphery of the central portion 12, but the outer edge portion 13 may be provided only on a part thereof.
As described above, the outer edge portion 13 surrounding the entire periphery of the display device 10 has a different outer surface direction for each portion, and the traveling direction of the emitted light is not uniform. Below, the appearance of the light emitted from the outer edge portion 13 will be described.

  FIG. 3 shows an example of a display mode using light emitted from the outer edge portion 13 when the display device 10 is viewed from the front. The shaded portion in FIG. 3 schematically represents light emitted from the outer edge portion 13. As described above, the main traveling direction of the light emitted from the outer edge portion 13 is the normal direction of the outer surface, and any portion of the entire outer edge portion 13 is normal to the outer surface. The direction is inclined outward from the front. Therefore, when the entire circumference of the outer edge portion 13 is illuminated, as shown in FIG. 3A, light is emitted to spread outward from the front of the display device 10 (the front side of the sheet of FIG. 3). Become.

  Here, the traveling direction of light emitted from the four corners of the outer edge portion 13 will be described. The outer surfaces of the left side portion and upper connection portion of the outer edge portion 13 are conical side surfaces, and light is emitted in the normal direction of the conical side surfaces. Since the normal direction of the conical side surface changes continuously according to the position on the surface, light is emitted from the connection portion without interruption along the outer periphery of the outer edge portion 13. Similarly, light is emitted from the right side portion and the upper connection portion of the outer edge portion 13 without interruption. In addition, the left side part and the upper part, and the right side part and the upper part of the outer edge part 13 correspond to the “first side part and second side part” of the present invention, respectively.

  On the other hand, in the left side portion and the lower connection portion of the outer edge portion 13, the left outer surface and the lower outer surface intersect at a right angle. Light is emitted in the normal direction from the outer surface facing left and the outer surface facing downward, but the normal direction changes discontinuously at the intersection at a right angle, so no light is emitted at the connection Occurs. Similarly, a direction in which light is not emitted occurs in the right side portion and the lower connection portion of the outer edge portion 13. The shape of the outer edge portion 13 is not limited to the shape of the present embodiment, and may be set in consideration of the influence on the direction in which light is emitted.

  As described above, light is emitted from the outer edge portion 13 so as to spread outward, whereas from the central portion 12, as described above with reference to FIG. 2, the front of the display device 10 (in FIG. 3). Since light is emitted toward the front side of the paper), the main traveling directions of the light emitted from the central portion 12 and the outer edge portion 13 are different from each other. For this reason, the irradiation ranges of the light emitted from the central portion 12 and the outer edge portion 13 are also different. In general, it is known that light of the same intensity illuminates brighter than light illuminated from an oblique direction. As described above, since the light irradiation range and the light intensity are different, the light emitted from the central portion 12 and the light emitted from the outer edge portion 13 are different in appearance to the driver. .

  For example, the display device 10 of this embodiment is installed on the left side when viewed from the driver's seat, and the outer surface of the outer edge portion 13 on the right side is directed to the driver side (see FIG. 1). The light emitted from the outer edge part 13 of the part enters the eyes of the driver at an angle closer to the vertical than the light emitted from the central part 12. Therefore, the light emitted from the outer edge 13 on the right side is felt bright for the driver. In addition, in the upper right part of the display device 10, the inclination of the outer surface of the outer edge portion 13 continuously changes from right to upward, so that even if the driver is looking down on the display device 10 from diagonally upward to the right. From any part, light is emitted at an angle close to perpendicular to the driver's eyes, and it looks bright.

  What the driver sees in different ways of lighting is not limited to the light that directly enters the driver's eyes, but the same applies to the indirect light that is reflected on the interior material of the vehicle 1 and then enters the driver's eyes. I can say. The main traveling direction of light emitted from the central portion 12 is forward, whereas light is emitted from the outer edge portion 13 so as to spread outward from the front of the display device 10 from the entire periphery. Therefore, the reflected light generated in a wider range enters the driver's eyes. For example, since the lower part of the outer edge part 13 is adjacent to the dashboard, the light emitted from the lower part of the outer edge part 13 is strongly reflected, and the driver can also see the light reflected on the dashboard. One of the modes of use of light by the outer edge portion 13 is to use it for decoration that changes the atmosphere in the vehicle interior by reflected light to the surroundings. Moreover, the following display modes can also be realized using such light from the outer edge portion 13.

  The light emitted from the outer edge portion 13 is light emitted from a region in the position corresponding to the outer edge portion 13 on the display surface of the liquid crystal display 14, and the light emitted from the central portion 12 is the center. It is light emitted from a region at a position associated with the unit 12. Therefore, since the light emitted from the central portion 12 and the light emitted from the outer edge portion 13 can be controlled separately by the display control portion 16, information by functions such as a car navigation system and a back monitor is displayed by the light of the central portion 12. On the other hand, it is possible to use such as displaying other information with the light of the outer edge portion 13. Moreover, by controlling by the display control part 16, it is not restricted to displaying using the perimeter of the outer edge part 13 as shown in FIG. 3A, but displaying using a part of the outer edge part 13. You can also.

  FIG. 3B shows how the display of the outer edge portion 13 is moved. By controlling the display of the outer edge portion 13 by the display control unit 16, it is possible to display a part of the outer edge portion 13 as shown in FIG. 3B and to move the position continuously. Here, as represented by the arrow in FIG. 3B, even if the display position of the outer edge portion 13 is moved from the right side portion to the upper portion of the outer edge portion 13, the connection portion between the right side portion and the upper portion of the outer edge portion 13. Since the shape is rounded as described above, it can be moved without interruption at this connecting portion.

  If the display by moving the light emitted from the outer edge portion 13 in this way is used, a part of the information displayed at the central portion 12 can be displayed at the outer edge portion 13. For example, it is possible to display the driving progress on the outer edge 13 while displaying information about the car navigation route guidance at the central portion 12. The total distance from the starting point to the destination is defined as the section from the left end to the right end at the lower part of the outer edge 13, and the current position on the section is flashed and the travel distance from the starting position to the current position is displayed as a bar graph. You can display the progress of the drive. Since the display of the outer edge portion 13 is conspicuous in a different way of lighting with respect to the display of the central portion 12, the driver can check the progress of the drive at a glance.

  Furthermore, the display of the outer edge portion 13 as shown in FIG. 3 (a) or FIG. 3 (b) can be drawn only when notifying specific information, thereby attracting the driver's attention. . Below, the outer edge part display process which the display control part 16 performs when utilizing the display of the outer edge part 13 for such a notification is demonstrated.

A-2. Outer edge display processing:
FIG. 4 shows a flowchart of outer edge display processing executed by the display control unit 16. The outer edge display process is started when the engine of the vehicle 1 is started and the power of the display device 10 is turned on, and a process for warning the driver that there is an obstacle around the vehicle 1 by displaying the outer edge 13. It is. When the outer edge display process is started, it is first determined whether or not obstacle information has been acquired (S101).

The obstacle information is information indicating the presence of an obstacle that may be contacted with the vehicle 1 and the direction in which the obstacle is present with respect to the vehicle 1, and is output from a radar system (not shown) mounted on the vehicle 1. The This radar system emits radio waves toward the periphery of the vehicle 1 and detects the presence / absence of an obstacle, the direction of the obstacle, and the distance to the obstacle based on the reflected wave. When an obstacle is detected in a predetermined range around the vehicle 1, obstacle information is output to the display device 10.
Obstacle information is merely an example of “specific information” of the present invention, and can be treated as “specific information” as long as it is information to be notified to the driver. Other information includes, for example, information for warning the possibility of lane departure and information for informing the switching of traffic signal display.

If the obstacle information has not been acquired (S101: no), the process waits until the obstacle information is acquired (S101). When the obstacle information is acquired (S101: yes), it is determined whether the obstacle is behind the vehicle 1 based on the acquired obstacle information (S102).
When there is an obstacle behind (S102: yes), display mode A is selected and display of the outer edge portion 13 is executed (S103). In the present embodiment, as the display mode A, a display mode that shines the entire circumference of the outer edge portion 13 is set as shown in FIG.

  When an obstacle is detected behind the vehicle 1, the display mode A is executed to inform the driver that there is an obstacle behind. For example, even if the display device 10 has the function of a back monitor and projects the scenery behind the vehicle 1 at the central portion 12, if the driver visually confirms the rear of the vehicle 1, The device 10 does not enter the driver's view. In this case, although it is difficult for the driver to notice even if it is displayed on the central portion 12, if it is displayed on the outer edge portion 13, the reflected light generated in a wide range is newly incident on the driver's field of view, so that the driver is made aware. be able to. This is particularly useful for warning that an obstacle is present at a position that becomes a blind spot when viewed from the back monitor or visually.

On the other hand, when there is no obstacle behind (S102: no), it is subsequently determined whether or not the obstacle is on the left side of the vehicle 1 (S104). When there is an obstacle on the left side (S104: yes), display mode B is selected and display of the outer edge portion 13 is executed (S105).
In the present embodiment, as the display mode B, a display mode is set in which a portion to be lit from the right side portion of the outer edge portion 13 toward the upper left end as shown in FIG. As described above, the outer surface of the outer edge portion 13 on the right side of the display device 10 is directed to the driver side (see FIG. 1), and light is emitted toward the driver by executing the display mode B. Even if the driver does not look at the display device 10, it is easy to notice.

  In addition, the display of the outer edge portion 13 is moved to the left in the display mode B, and the driver's eyes catch the movement, whereby the driver's line of sight is guided to the left. By doing so, it is possible to convey information that there is an obstacle on the left side without causing the driver to think about the meaning of being displayed on the outer edge portion 13. In addition, since the driver's line of sight has already been guided to the left during this information transmission, the time until the driver visually recognizes the actual obstacle can be shortened very much.

  As described above, in the outer edge display processing of the present embodiment, the display mode A and the display mode B are greatly different for each notification content, so that the display mode A and the display mode B are mistakenly interpreted. There is little risk of it occurring. Further, in order to prevent the both from being confused with certainty, the display mode A may be displayed in red, and the display mode B may be displayed in blue.

When display of display mode A or display mode B is thus executed (S103, S105), it is determined whether or not the obstacle information has been released (S106). When the radar system no longer detects an obstacle, the obstacle information is canceled.
If the obstacle information has not yet been released (S106: no), the display at the outer edge 13 is continued. Thereafter, when the obstacle information is released (S106: yes), the display at the outer edge portion 13 is terminated (S107), the process returns to the head of the outer edge portion display processing (S101), and the obstacle information is acquired again. From the determination (S101), a series of processing is repeated.

On the other hand, if it is determined in S104 that there is no obstacle on the left side (S104: no), the display of the display mode A or the display mode B is not executed, and the head of the outer edge display process (S101) is performed. Return and repeat the series of processing.
In addition, when a separate display device is provided on the right side when viewed from the driver's seat of the vehicle 1 and there is an obstacle on the right side, the driver's line of sight is guided to the right in the same manner as the display mode B described above. May be.

B. Modified example:
In the above-described embodiment, even light emitted in the same manner from the liquid crystal display 14 is emitted in different directions by passing through either the central portion 12 or the outer edge portion 13 having different outer surface directions. It was like that. However, the configuration for emitting light emitted from the same liquid crystal display 14 in different directions is not limited thereto. Below, the modification containing the structure which refracts the light emitted from the liquid crystal display 14 is demonstrated.

  FIG. 5 shows a cross-sectional view of the upper part of the modified display device 10 taken along line AA of FIG. In FIG. 5, illustration of components other than the glass plate 11 is omitted, but the basic configuration of the modification is the same as that of the above-described embodiment. Further, in the modified example, it is assumed that the light emitted from the liquid crystal display 14 is unified in advance to the light traveling toward the front of the display device 10 (left side in FIG. 5).

  As shown in FIG. 5A, the outer edge portion 13 of the present modification has a shape in which the outer surface is on the same plane as the outer surface of the central portion 12, and the rear surface of the outer edge portion 13 (on the liquid crystal display 14 side). The surface is directed diagonally downward. The outer edge portion 13 is a so-called prism. When light traveling forward of the display device 10 is incident on the back surface of the outer edge portion 13, the outer edge portion 13 is refracted according to the incident angle. Then, when light traveling straight in the outer edge portion 13 enters the outer surface, it is refracted again and emitted outside the outer edge portion 13. For this reason, the direction in which light is emitted is not the normal direction of the outer surface of the outer edge portion 13 (in front of the display device 10) but obliquely upward.

On the other hand, when the light toward the front of the display device 10 is incident on the back surface of the central portion 12, it is not refracted because it is perpendicularly incident on the back surface and the outer surface of the central portion 12. Released outside. Therefore, the direction in which light is emitted is the normal direction of the outer surface of the central portion 12 (in front of the display device 10).
In this way, light can be emitted in a direction different from the central portion 12 by refracting using the prism as the outer edge portion 13. The arrangement angle of the prism as the outer edge portion 13 and the direction of incident light are not limited to the example shown in FIG. 5 and can be changed as appropriate.

In general, light emitted from the liquid crystal display 14 includes three colors of red (R), green (G), and blue (B). When such light containing RGB (for example, white light) is incident on the outer edge portion 13, as shown in FIG. 5B, the refractive index differs depending on the wavelength of the color. It is discharged out of the outer edge 13. Further, if the incident light includes various wavelengths such as sunlight, the light emitted from the outer edge portion 13 will appear iridescent.
On the other hand, when light containing RGB enters the central portion 12, it is not refracted, and is therefore not emitted and is directly emitted outside the outer edge portion 13. By doing so, the light emitted from the outer edge portion 13 and the light emitted from the central portion 12 are seen in different colors, and the difference in how they are seen becomes more conspicuous.

  As mentioned above, although the present Example and the modified example were demonstrated, this invention is not restricted to said Example and modified example, In the range which does not deviate from the summary, it can implement in a various aspect.

For example, in the embodiment described above, the central portion 12 and the outer edge portion 13 of the glass plate 11 are integrally formed. However, these are configured as separate members, and light is transmitted between the central portion 12 and the outer edge portion 13. A light shielding film for shielding may be provided. In this way, the light reflected by the outer surface of the outer edge portion 13 does not enter the central portion 12 (see FIG. 2), and the adverse effect such as making it difficult to see the display of the central portion 12 by the light incident from the outer edge portion 13. Can be prevented.
Further, a reflective film may be provided in place of the light shielding film. In this way, the light reflected by the outer surface of the outer edge portion 13 is not only prevented from entering the central portion 12 but also reflected, and the reflected light can also be emitted from the outer edge portion 13 to the outside.

  Moreover, the outer edge part 13 should just be able to discharge | emit light in the direction different from the center part 12, and can also diverge | emit or focus the emitted light in that case. For example, a part or all of the outer edge portion 13 may be a lens shape. Further, each of the outer surface and the rear surface of the outer edge portion 13 does not have to be a single surface as shown in FIG. 2 or FIG. 5, and may be composed of a plurality of surfaces. For example, the outer edge portion 13 can be made thin or the traveling direction of light emitted from the outer edge portion 13 can be adjusted by forming a so-called flat prism shape that repeatedly forms small inclined surfaces with different angles. Further, the traveling direction of the light emitted from the outer edge 13 can be adjusted by covering the outside of the outer edge 13 with a frame 15 or the like, and the light emitted from the outer edge 13 is the glass of the vehicle 1 such as a windshield or a side glass. It is possible to reduce the amount of reflection in the image.

Moreover, by providing an optical structure that emits light in the normal direction of the outer surface on the outer surface of the outer edge portion 13, it is possible to suppress the diffusion of light and reduce the above-described reflection. As such an optical structure, for example, there is a fine projection group (so-called moth-eye structure) on a substantially cone arranged regularly at intervals smaller than the wavelength of visible light. The moth-eye structure is often used as an antireflection material for displays, but it is also known that the main traveling direction of light passing through the surface provided with the moth-eye structure is the normal direction of the surface. It has been.
If a moth-eye structure is provided on the outer surface of the central portion 12 together with the outer surface of the outer edge portion 13, the traveling direction of light emitted from the central portion 12 (see FIG. 2A) and the outer edge portion 13 are emitted. The difference from the traveling direction of light (see FIG. 2B) can be made more conspicuous. On the other hand, if the moth-eye structure is not provided on the outer surface of the outer edge portion 13, the light emitted from the outer edge portion 13 can be diffused to widen the viewing angle of display.

DESCRIPTION OF SYMBOLS 1 ... Vehicle, 10 ... Display apparatus, 11 ... Glass plate,
12 ... Central part, 13 ... Outer edge part, 14 ... Liquid crystal display,
15 ... Frame body, 16 ... Display control part.

Claims (4)

A display device (10) mounted on a vehicle (1) for displaying an image,
A light source (14) for emitting light for displaying the image toward the front side of the display device;
A front body (11) provided in front of the display device ;
A display control unit (16) for controlling the light source to display the image ,
The front body has a central portion (12) occupying a predetermined region at the substantially center of the front body, and an outer edge portion (13) provided along the outer periphery of the central portion,
From the central portion, the light of the light source is emitted toward the front of the display device,
From the outer edge portion, the light of the light source is emitted to the outside of the central portion with respect to the light emitted from the central portion ,
When the display control unit acquires specific information to be notified to the driver, the display control unit controls a region associated with the outer edge portion of the light source to move a portion emitting light from the outer edge portion. A display device that executes display corresponding to the specific information . The display device according to claim 1,
The specific information is a display device that is information related to an obstacle detected around the vehicle . The display device according to 請 Motomeko 2,
When the display control unit acquires the specific information indicating that the obstacle is on a side opposite to the driver's seat of the vehicle, the display control unit moves from the driver's seat side toward the obstacle side. A display device that performs display for moving a portion emitting light from an outer edge .   A light source that is applied to a vehicle equipped with a display device for displaying an image and that emits light for displaying the image toward the front side of the display device; and a front body provided on the front surface of the display device; The front body includes a central portion that occupies a predetermined region at a substantially central portion of the front body, and an outer edge portion provided along an outer periphery of the central portion, and light from the light source is provided from the central portion. Is emitted toward the front of the display device, and the light from the light source is emitted from the outer edge portion to the outside of the central portion with respect to the light emitted from the central portion. Because
  Obtaining predetermined information to be notified to the driver (S102);
  When the predetermined information is acquired, the display corresponding to the predetermined information is executed by controlling the light incident on the outer edge portion of the front body and moving the portion emitting light from the outer edge portion. Process (S103, S105) and
  With
  Display control method.

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