JP6947148B2 - Display device - Google Patents

Description

The disclosure by this specification relates to a display device used in a vehicle.

Conventionally, for example, Patent Document 1 discloses that a curved display that displays information on a curved display surface is used as an in-vehicle device. Specifically, Patent Document 1 exemplifies the adoption of a curved display for an electronic mirror device, a CID (Center Information Display), a cluster portion, and the like.

JP-A-2017-181819

When a curved display such as the curved display of Patent Document 1 is mounted on a vehicle, the external light incident on the vehicle interior is focused on a specific focusing range due to reflection on the display surface of the curved display. If such a light-collecting range is directed toward the center of the eyelips of the driver's seat, the driver will visually recognize the display complicated by the outside light. As described above, the curved display has a concern that the visibility is significantly deteriorated due to the external light.

An object of the present disclosure is to provide a display device capable of reducing deterioration of visibility due to external light even if a curved display device is adopted.

In order to achieve the above object, one disclosed embodiment is a display device used in a vehicle (A) and displaying information toward a predetermined eye lip (EyL) for the driver's seat of the vehicle. A curved display (30) that displays information on the curved display surface (31) and an adjustment axis (Ax) that adjusts the orientation of the display surface are set on the curved display, and external light reflected on the display surface is set. The adjustment mechanism (40, 340, 440) that makes it possible to change the orientation of the display surface around the adjustment axis so that the light collection range of (OL) deviates from the center of the irips (CEL), and the external light incident on the display surface. Adjustment to change the orientation of the display surface so that the condensing range is far from the center of the irips based on the external light grasping unit (71) that grasps the situation of The curved display can be stored in the execution unit (72) and the storage room (4) partitioned by the vehicle, and the curved display is moved from the stored state stored in the storage room to the activated state for displaying information. receiving mechanism (50) includes a adjustment execution unit, in its travel up the curved display is activated state from the stored state, the display condensing range that controls the adjustment mechanism so that off-center of Airipusu It is said to be a device.
Further, one disclosed aspect is a display device used in a vehicle (A) that displays information toward a predetermined eye lip (EyL) for the driver's seat of the vehicle, and is a display surface in a curved state. A curved display (30) that displays information on (31) and an adjustment axis (Ax) that adjusts the orientation of the display surface are set on the curved display, and the external light (OL) reflected on the display surface is collected. It is equipped with an adjustment mechanism (40, 340, 440) that allows the orientation of the display surface to be changed around the adjustment axis so that the range deviates from the center of the irips (CEL), and the adjustment mechanisms display at different locations. It is a display device having a plurality of curvature adjusting units (343, 344) for individually adjusting the curvature of the curvature of the surface, and the plurality of curvature adjusting units set a virtual adjustment axis on the curvature display.

In these embodiments, the adjustment shaft for adjusting the orientation of the display surface are set for the curved display. Then, by adjusting the orientation of the display surface around the adjustment axis, the focusing range of the external light reflected on the display surface deviates from the center of the irips. According to the above, the display complicated by the external light becomes difficult to be visually recognized. Therefore, even in a display device that employs a curved display that displays information on a curved display surface, deterioration of visibility due to external light can be reduced.

The reference numbers in parentheses are merely examples of the correspondence with the specific configuration in the embodiment described later, and do not limit the technical scope at all.

It is a figure which shows the vehicle-mounted state of the display device by 1st Embodiment. It is a block diagram which shows the electrical structure of a display device. It is a figure explaining that the light condensing range by an external light reflected light deviates from the center of an iris by the rotation of an EL display. It is a flowchart which shows the detail of the display control processing performed by a display controller. It is a block diagram which shows the electrical structure of the display device by 2nd Embodiment. It is a figure explaining that the light-collecting range deviates from the center of an iris by the rotation of an EL display. It is a figure which shows the vehicle-mounted state of the display device by 3rd Embodiment. It is a block diagram which shows the electrical structure of a display device. It is a figure explaining that the light condensing range by an external light reflected light deviates from the center of an iris by the rotation of an EL display. It is a figure which shows the vehicle-mounted state of the display device of the modification 1 in which a plurality of adjustment axes are set.

Hereinafter, a plurality of embodiments of the present disclosure will be described with reference to the drawings. By assigning the same reference numerals to the corresponding components in each embodiment, duplicate description may be omitted. When only a part of the configuration is described in each embodiment, the configuration of the other embodiment described above can be applied to the other parts of the configuration. Further, not only the combination of the configurations specified in the description of each embodiment but also the configurations of a plurality of embodiments can be partially combined even if the combination is not specified. Further, an unspecified combination of the configurations described in the plurality of embodiments and modifications is also disclosed by the following description.

(First Embodiment)
The display device 100 according to the first embodiment of the present disclosure shown in FIG. 1 is used in the vehicle A and is installed in front of the driver's seat as a display device that replaces the combination meter. The display device 100 presents various information related to the vehicle A to the driver sitting on the driver through the display on the display surface 31. The image generation device 21 and the external light sensor 22 shown in FIG. 2 are directly or indirectly electrically connected to the display device 100.

The image generation device 21 is a control device that integrally controls the display of a plurality of display devices mounted on the vehicle A (see FIG. 1). The image generation device 21 is mainly composed of a circuit that generates an image displayed on each display device. The video generator 21 is connected to the vehicle-mounted network 23. The video generation device 21 generates a video signal to be output to each display device based on the vehicle information acquired from the vehicle-mounted network 23. The video generation device 21 generates a video signal including, for example, a speedometer and a status indicator of a driving support system, and sequentially outputs the video signal to the display device 100 and the like.

As shown in FIGS. 1 and 2, the external light sensor 22 detects the external light OL that shines into the vehicle interior through the front windshield WS, the side window SG, or the like. The external light sensor 22 is installed on, for example, the upper surface of the instrument panel 2. As an example, the detection result by the external light sensor 22 is used for lighting control of the headlight or the like of the vehicle A. The external light sensor 22 has a light receiving element that detects the illuminance of the external light OL. The external light sensor 22 is provided with a plurality of light receiving elements so that the incident direction of the external light OL can be specified. The detection result of the external light OL by each light receiving element is sequentially output to the display device 100.

The display device 100 is installed on the upper surface of the instrument panel 2 in the vehicle interior of the vehicle A with the display surface 31 facing the driver's seat side. The display device 100 displays information on the driver's seat toward the pre-defined Eye Lips EyL (see FIG. 3). The Ellipsoidal EyeL is a virtual area defined for each vehicle type, and is a virtual ellipsoid above the seat surface of the driver's seat and near the headrest based on the eye range that statistically represents the distribution of the driver's eye positions. (See JISD0021: 1998). The driver who positions the eye point on the eye lip EyL visually recognizes the display surface 31 of the display device 100 above the steering wheel 5.

In the description of the present disclosure, expressions relating to directions such as front-back, up-down, left-right, etc. are defined with reference to the vehicle A placed on a horizontal plane. The right and left are defined based on the driver seated in the driver's seat.

The display device 100 includes an EL (Electro Luminescence) display 30, a movable base portion 39, an adjustment mechanism 40, a storage mechanism 50, a display controller 60, and the like.

The EL display 30 is formed in a horizontally long plate shape by a transparent substrate made of a flexible transparent resin. Of both sides of the EL display 30, one facing the driver's seat side is the display surface 31, and the other side facing the front of the vehicle A located on the opposite side of the display surface 31 is the back surface 33. On the transparent substrate of the EL display 30, a transparent electrode layer on which a transparent electrode made of a thin film of ITO (Indium Tin Oxide) is formed, and a light emitting layer electrically connected to the transparent electrode are provided. In the light emitting layer, red, green, and blue light emitters made of an organic EL material are regularly two-dimensionally arranged so as to form individual light emitting pixels. The EL display 30 emits and displays an image in full color on the display surface 31 by causing each light emitting pixel to emit light by applying a current to each light emitting body through a transparent electrode.

The EL display 30 becomes a flexible display panel, and can display information on a curved display surface 31. The display surface 31 has a concave cylindrical shape having a curvature in the vertical (short) direction. The central axis, which is the center of curvature of the display surface 31, is in a horizontally extended posture along the longitudinal direction of the EL display 30. The curvature of the display surface 31 in the vertical direction may be continuously changed.

The movable base portion 39 is located below the EL display 30, and indirectly supports the EL display 30 with respect to the instrument panel 2. The movable base portion 39 can be moved up and down with respect to the instrument panel 2 by the operation of the storage mechanism 50. In the state of being lifted by the storage mechanism 50, the movable base portion 39 becomes the lid portion of the storage chamber 4 partitioned by the instrument panel 2. At this time, the upper surface of the movable base portion 39 is continuous with the upper surface of the instrument panel 2.

The adjustment mechanism 40 is a mechanism for setting the adjustment shaft Ax for adjusting the orientation of the display surface 31 on the EL display 30. The adjustment shaft Ax is defined along the yaw axis of the vehicle A and makes the EL display 30 rotatable in the horizontal direction. The adjustment shaft Ax is defined at a position slightly deviated from the center of the display surface 31 in the horizontal (longitudinal) direction toward the back side. The adjusting mechanism 40 has a movable holding portion 41 and an attitude control motor 42.

The movable holding portion 41 is formed in a curved plate shape that covers the back surface 33 of the EL display 30 by, for example, a resin material having the same texture as the instrument panel 2 or the like. The movable holding portion 41 is attached to the back surface 33 of the EL display 30, and rotatably supports the EL display 30 with respect to the movable base portion 39 held by the instrument panel 2. The movable holding unit 41 sets the adjustment axis Ax on the EL display 30, and enables displacement of about 3 to 5 ° in the left and right swing directions. The movable holding portion 41 can impart an angular component in the yaw direction to the EL display 30.

The attitude control motor 42 is a drive unit that drives the EL display 30 around the adjustment shaft Ax. The attitude control motor 42 is fixed to the movable base portion 39, and causes the movable holding portion 41 and the EL display 30 to rotate relative to the movable base portion 39. The attitude control motor 42 is composed of a motor body, a reduction gear mechanism, and the like. The motor body is a permanent magnet type stepper motor, and includes an output shaft integrally formed with a magnet, a fixed portion integrally formed with a coil, and the like. The reduction gear mechanism transmits the rotation of the output shaft to the movable holding unit 41 while decelerating it. The attitude control motor 42 rotates the output shaft of the motor body based on the pulse signal input from the display controller 60. As a result, the phase adjustment of the EL display 30 and the movable holding portion 41 is realized.

The storage mechanism 50 is an elevating mechanism that enables the EL display 30 to be stored in the storage chamber 4 partitioned by the instrument panel 2. The storage mechanism 50 moves the EL display 30 in the vertical direction from the stored state to the activated state. In the stored state, substantially the entire EL display 30 is housed in the storage chamber 4. On the other hand, in the activated state, the entire EL display 30 protrudes above the instrument panel 2. As a result, in the activated state, the information display on the display surface 31 becomes visible from the eye lip EyL (see FIG. 3).

The storage mechanism 50 has a storage control motor 51. The storage control motor 51 has an EL display 30, a movable base portion 39, and a movable holding portion 41 (hereinafter, “movable configuration”) along an elevating rail provided on a vehicle A (for example, an instrument panel 2 or a reinforcement). It is a drive unit that moves up and down. The storage control motor 51 is fixed to the vehicle A together with the elevating rail, and the movable configuration is relatively displaced in the vertical direction with respect to the instrument panel 2.

The storage control motor 51 is composed of a motor body, a conversion mechanism, and the like. The motor body is a stepper motor similar to the attitude control motor 42, and has a configuration having a higher output than the attitude control motor 42. The conversion mechanism is a mechanism that converts the rotational movement of the output shaft of the motor body into linear operation along the elevating rail. The storage control motor 51 rotates the output shaft of the motor body based on the pulse signal input from the display controller 60. As a result, the movable structure can be moved up and down.

The display controller 60 is an electric circuit that controls the operations of the EL display 30, the attitude control motor 42, and the storage control motor 51. The display controller 60 is fixed to, for example, the movable base portion 39 and is electrically connected to each of the electric configurations (30, 42, 51). The display controller 60 is fixed to the vehicle side and may be electrically connected to each electrical configuration via flexible wiring.

The display controller 60 is mainly composed of a microcontroller or a control board having at least one processor 61, a RAM coupled to the processor 61, a memory device 62 including a storage medium, an input / output interface, and the like. The memory device 62 stores a plurality of control programs and the eigenvalues of the vehicle A used in each control program. Specifically, the memory device 62 stores a state control program that controls the position and orientation of the EL display 30 and a display control program that controls the display by the EL display 30. The display controller 60 has functional units such as an external light grasping unit 71, a mechanism control unit 72, and a display control unit 73 by executing each control program by the processor 61.

The external light grasping unit 71 acquires the detection result of the external light OL by each light receiving element from the external light sensor 22. The external light grasping unit 71 calculates the incident direction and illuminance of the external light OL shining into the vehicle interior, particularly the direct light incident directly shining from the sun position, based on the detection results of the plurality of light receiving elements. In addition, the external light grasping unit 71 includes parameter information (hereinafter, “vehicle interior information”) indicating the shape and arrangement of each window, and parameter information (hereinafter, “vehicle interior information”) indicating the shape and arrangement of the EL display 30 in the activated state. “Display information”) is read from the memory device 62. The external light grasping unit 71 grasps the state of the external light OL incident on the display surface 31 based on the identified state information of the external light OL, the vehicle interior information, the display information, and the like. As an example, the external light grasping unit 71 grasps the incident angle and the illuminance of the external light OL incident on the center of the display surface 31 as the external light condition. The external light grasping unit 71 may target not only the external light OL directly incident on the display surface 31 but also the external light OL incident on the display surface 31 after being reflected by the side window SG or the like.

The mechanism control unit 72 generates a pulse signal output to each of the attitude control motor 42 and the storage control motor 51. The mechanism control unit 72 controls each operation of the adjusting mechanism 40 and the accommodating mechanism 50 by supplying pulse signals to the control motors 42 and 51. The mechanism control unit 72 can perform microstep control on the attitude control motor 42, and can adjust the orientation of the display surface 31 with high accuracy.

As shown in FIGS. 1 to 3, the mechanism control unit 72 has a posture in which the display surface 31 faces the center of the eye lip EyL (hereinafter, “irip center CEL”) as normal control for the attitude control motor 42 (hereinafter, “the posture center CEL”). The adjustment mechanism 40 is controlled so as to have a "reference posture"). When the illuminance of the external light OL grasped by the external light grasping unit 71 exceeds a specific threshold value, the mechanism control unit 72 changes the orientation of the display surface 31 from the reference posture as a control different from the normal one.

More specifically, in the display device 100, since the display surface 31 has a curved shape, the external light OL reflected by the display surface 31 (hereinafter, “external light reflected light OLr”) is within a specific focusing range. It is focused. The light-collecting range is visually recognized by the driver as a point-like or linear light-emitting area, which reduces the visibility of the display surface 31. Therefore, the mechanism control unit 72 changes the direction of the display surface 31 by the adjusting mechanism 40 so as to remove the condensing range of the external light reflected light OLr from the iris center CEL.

For such control, the mechanism control unit 72 determines the external light reflected light OLr based on the external light condition grasped by the external light grasping unit 71, specifically, the incident angle of the external light OL on the display surface 31. Calculates the optical axis that indicates the direction of travel. In addition to the above display information, the mechanism control unit 72 reads the position information of the iris center CEL from the memory device 62. The mechanism control unit 72 grasps the positional relationship between the optical axis of the external light reflected light OLr and the iris center CEL by geometric calculation. When the condensing range of the external light reflected light OLr overlaps with the iris center CEL, the mechanism control unit 72 directs the display surface 31 so that the optical axis of the external light reflected light OLr moves away from (disengages) from the iris center CEL. Perform control to change. The mechanism control unit 72 controls the adjustment mechanism 40 so as to exclude the condensing range of the external light reflected light OLr from the entire area of the irips EyL.

Here, the change angle of the optical axis of the external light reflected light OLr is twice the rotation angle of the EL display 30. That is, when the EL display 30 is rotated by n °, the optical axis of the external light reflected light OLr changes by 2 n °.

The mechanism control unit 72 causes the storage mechanism 50 to perform an ascending / descending operation of a movable configuration based on switching between an on state and an off state of the vehicle power supply. Specifically, when the vehicle power is switched from the off state to the on state (hereinafter, “at startup”), the mechanism control unit 72 operates the storage mechanism 50 and the EL is stored in the storage chamber 4. Raise the display 30 to the activated position. On the other hand, when the vehicle power is switched from the on state to the off state (hereinafter, "when stopped"), the mechanism control unit 72 operates the storage mechanism 50 and lowers the EL display 30 in the activated state position. And store it in the storage room 4.

The mechanism control unit 72 described above adjusts the EL display 30 so that the focusing range of the external light reflected light OLr deviates from the iris center CEL in the rising movement stroke from the stored state to the activated state when the EL display 30 is started. 40 is controlled. Similarly, the mechanism control unit 72 controls the adjustment mechanism 40 so that the focusing range deviates from the iris center CEL even in the moving stroke from the activated state to the retracted state when the EL display 30 is stopped.

The display control unit 73 acquires a video signal defining the display of the EL display 30 from the video generator 21. The display control unit 73 drives each pixel of the EL display 30 based on the content of the acquired video signal, and displays an image according to the video signal on the display surface 31. The display control unit 73 corrects the image to be displayed on the display surface 31 based on the external light condition grasped by the external light grasping unit 71. As a basic correction control, the display control unit 73 adjusts the display brightness of the display surface 31 higher as the illuminance of the external light OL shining into the vehicle interior becomes higher.

Further, when the orientation of the display surface 31 is adjusted by the mechanism control unit 72, the display control unit 73 corrects the shape of the image, the emission brightness, and the emission color according to the phase of the EL display 30. More specifically, the image of the display surface 31 viewed from an oblique direction has a distorted shape with respect to the image of the display surface 31 viewed from the front. In addition, the emission brightness and emission color of each pixel when the display surface 31 is viewed from an oblique direction may be different from the emission brightness and emission color when the display surface 31 is viewed from the front. Therefore, the memory device 62 stores in advance correction data that defines correction amounts for image shape distortion, emission brightness, and emission color. The display control unit 73 executes image shape correction, luminance correction, and color correction in accordance with a change in the orientation of the display surface 31 by applying the phase of the EL display 30 to the correction data.

Next, the details of the display control process for controlling the state of the EL display 30 according to the situation of the external light OL will be described with reference to FIGS. 1 to 3 based on FIG. The display control process shown in FIG. 4 is started by the display controller 60 when the power supply is started based on the switching of the vehicle power supply to the on state. The display control process is continuously started until the storage of the EL display 30 in the storage chamber 4 is completed.

In S101, based on the detection result acquired from the external light sensor 22, the state of the external light OL incident on the display surface 31 is grasped, and the process proceeds to S102. In S102, the focusing range of the external light reflected light OLr reflected on the display surface 31 is specified based on the condition of the external light grasped in S101, and the process proceeds to S103.

In S103, the positions of the light condensing range of the external light reflected light OLr and the predetermined iris center CEL are calculated, and the presence or absence of the overlap between the condensing range and the iris center CEL is determined. When it is determined in S103 that the focusing range is out of the iris center CEL, S104 is skipped and the display control process is terminated.

On the other hand, if it is determined in S103 that the focusing range overlaps with the iris center CEL and the external light reflected light OLr is focused on the iris center CEL, the process proceeds to S104. In S104, the phase of the EL display 30 in which the focusing range does not overlap with the iris center CEL is calculated. Then, the control of rotating the EL display 30 to the calculated phase is executed, and the orientation of the display surface 31 is adjusted. In addition, in S104, the shape of the image, the emission brightness, and the emission color are adjusted so that the aspect of the image seen from the eyelips center CEL does not change according to the rotation of the EL display 30, and the display control process is terminated.

According to the first embodiment described so far, the adjustment axis Ax for adjusting the orientation of the display surface 31 is set with respect to the EL display 30. Then, by adjusting the EL display 30 to rotate around the adjustment axis Ax, the focusing range of the external light OL reflected on the display surface 31 is deviated from the iris center CEL. According to the above, the display complicated by the external light OL is hard to be visually recognized by the driver. Therefore, even in the display device 100 that employs the EL display 30 that displays information on the curved display surface 31, it is possible to reduce the deterioration of visibility due to the external light OL.

In addition, in the first embodiment, the orientation of the display surface 31 is automatically changed so that the condensing range is away from the iris center CEL based on the condition of the external light grasped by the external light grasping unit 71. Therefore, even if the traveling direction of the vehicle A and the condition of the external light OL change, the display device 100 can maintain a state in which the focusing range is excluded from the iris center CEL.

Further, the display device 100 of the first embodiment can store the EL display 30 in the storage chamber 4 by operating the storage mechanism 50. Even with such a configuration, the state in which the light collection range is removed from the iris center CEL is maintained in the moving process from the stored state stored in the storage chamber 4 to the activated state in which the vehicle information is displayed. Similarly, in the moving process from the activated state to the stored state, the state in which the light collecting range is removed from the iris center CEL is maintained. According to the above, the effect of reducing the deterioration of visibility can be continuously exhibited even after the display device 100 is started and stopped.

Further, in the first embodiment, the movable holding portion 41 defines the actual adjustment shaft Ax. If the EL display 30 is rotated around the adjustment axis Ax as the center of rotation, the orientation of the display surface 31 can change stably. Therefore, the mechanism control unit 72 can accurately control the adjustment mechanism 40 so that the focusing range deviates from the iris center CEL.

In addition, in the first embodiment, the shape, emission brightness, and emission color of the image displayed on the display surface 31 are corrected according to the change in the orientation of the display surface 31. Therefore, the apparent display change associated with the control of removing the focusing range from the iris center CEL can be suppressed. Therefore, it is possible to make adjustments to reduce the deterioration of visibility without causing the driver to feel uncomfortable.

Further, in the first embodiment, the mechanism control unit 72 adjusts the orientation of the display surface 31 only when the illuminance of the external light OL grasped by the external light grasping unit 71 is equal to or higher than the threshold value. .. Therefore, the orientation adjustment of the display surface 31 based on the detection of the light of a weak light source such as a street lamp at night is not performed. Based on the above, the disadvantages that the screen becomes difficult to see or the movement becomes complicated due to the adjustment of the orientation of the display surface 31 are unlikely to occur.

In the first embodiment, the EL display 30 corresponds to the "curved display", the movable base unit 39 corresponds to the "base portion", and the mechanism control unit 72 corresponds to the "adjustment execution unit".

(Second Embodiment)
The second embodiment shown in FIGS. 5 and 6 is a modification of the first embodiment. The display device 200 according to the second embodiment is installed on the upper center surface of the instrument panel as, for example, a center information display. From the display device 200, the configuration corresponding to the storage mechanism 50 (see FIG. 2) of the first embodiment is omitted. In addition, in the display device 200, the details of the display controller 60 and the EL display 30 are different from those of the first embodiment.

The display controller 60 is directly or indirectly electrically connected to the vehicle-mounted network 23 and the navigation device 24. The display controller 60 executes a program stored in the memory device 62 by the processor 61, and includes functional units such as an external light grasping unit 71, a mechanism control unit 72, and a display control unit 73, as in the first embodiment.

The external light grasping unit 71 acquires information from the navigation device 24 instead of the external light sensor 22 (see FIG. 2). Specifically, the external light grasping unit 71 acquires the current position and the current direction of the vehicle A from the navigation device 24. The external light grasping unit 71 estimates the relative position of the sun with respect to the vehicle A based on the current time and the current position acquired from the navigation device 24. Then, the external light grasping unit 71 grasps the incident direction of the external light OL shining into the vehicle interior, and by extension, the incident angle of the external light OL incident on the display surface 31 as the external light condition based on the current orientation of the vehicle A. .. Further, the external light grasping unit 71 can grasp, for example, whether the external light OL is forward light or backlight, and the incident position of the external light OL as parameters of the external light environment.

Similar to the first embodiment, the mechanism control unit 72 controls the operation of the adjustment mechanism 40 by outputting a pulse signal toward the attitude control motor 42. On the other hand, the control function of the storage mechanism 50 (see FIG. 2) is omitted from the mechanism control unit 72 of the second embodiment.

In addition to the display control function of the EL display 30, the display control unit 73 further has a video generation function corresponding to the video generation device 21 (see FIG. 2) of the first embodiment. The display control unit 73 acquires vehicle information necessary for video generation from the vehicle-mounted network 23, and generates video data including a speedometer and the like to be displayed on the display surface 31. The display control unit 73 also executes shape correction, luminance correction, and color correction according to the rotation angle of the EL display 30 in the video data generation process.

The EL display 30 is fixed to the movable holding portion 41 in a state of being curved in the longitudinal direction. The display surface 31 has a concave cylindrical shape having a curvature in the horizontal direction. The central axis, which is the center of curvature of the display surface 31, is in a posture extending in the vertical (vertical) direction along the lateral direction of the EL display 30. Even in the second embodiment, the curvature of the display surface 31 in the horizontal direction may be continuously changed.

As in the first embodiment, the adjustment axis Ax is set on the EL display 30 by the adjustment mechanism 40. The adjustment shaft Ax is defined at a position along the yaw axis of the vehicle A and slightly deviated from the center of the display surface 31 in the horizontal direction to the front side. The EL display 30 can rotate in the horizontal direction integrally with the movable holding portion 41 with the adjustment shaft Ax as the center of rotation.

Also in the second embodiment described so far, the focusing range of the external light reflected light OLr can be removed from the center CEL of the irips EyL by the operation of rotating the EL display 30 around the adjustment shaft Ax. As a result, even in the display device 200 that employs the EL display 30 that displays information on the curved display surface 31 with the same effect as that of the first embodiment, it is possible to reduce the deterioration of visibility due to the external light OL. Become.

(Third Embodiment)
The third embodiment shown in FIGS. 7 to 9 is another modification of the first embodiment. The display device 300 according to the third embodiment is provided with an adjustment mechanism 340 having a configuration different from that of the first embodiment. The adjusting mechanism 340 includes two curvature adjusting units 343 and 344 and two curvature control motors 345.

The curvature adjusting portions 343 and 344 are attached to the back surface 33 of the EL display 30 at different positions from each other. Specifically, the curvature adjusting unit 343 holds the upper right corner 32r of the EL display 30. On the other hand, the curvature adjusting unit 344 holds the upper left corner 32l of the EL display 30. Each of the curvature adjusting units 343 and 344 can be operated separately, and adjusts the curvature of the curvature of the display surface 31 individually on the left and right sides.

More specifically, when the curvature adjusting unit 343 moves the upper right corner 32r of the EL display 30 upward, the curvature on the right side of the display surface 31 becomes smaller. When the curvature adjusting unit 343 moves the upper right corner 32r of the EL display 30 downward, the curvature on the right side of the display surface 31 becomes large. Similarly, when the curvature adjusting unit 344 moves the upper left corner 32l of the EL display 30 upward, the curvature on the left side of the display surface 31 becomes smaller. When the curvature adjusting unit 344 moves the upper left corner 32l of the EL display 30 downward, the curvature on the left side of the display surface 31 becomes large.

One curvature control motor 345 is provided in each of the curvature adjusting portions 343 and 344. The curvature control motor 345 drives each of the curvature adjusting units 343 and 344 based on the pulse signal input from the display controller 60. Each curvature control motor 345 is electrically connected to the mechanism control unit 72 (see FIG. 8) and is individually driven by the mechanism control unit 72. Each curvature control motor 345 is fixed to the base portion 339, and causes each curvature adjusting portion 343, 344 to perform an operation of moving the upper corners 32r and 32l up and down.

The adjustment mechanism 340 sets a virtual adjustment axis Ax on the EL display 30 by a plurality (two) curvature adjustment units 343 and 344. More specifically, if the left and right curvatures of the display surface 31 are substantially the same as each other, the display surface 31 is in a state of facing directly in front of the center CEL of the eye lip EyL. When the curvature on the right side of the display surface 31 is made larger than that on the left side by the operation of each of the curvature adjusting units 343 and 344, the display surface 31 is in a state of facing the right side. Further, when the curvature of the left side of the display surface 31 is made larger than that of the right side, the display surface 31 is in a state of facing the left side. As described above, the curvature adjusting units 343 and 344 can change the orientation of the display surface 31 around the virtual adjustment axis Ax by moving the upper corners 32r and 32l up and down.

Also in the third embodiment described so far, it is possible to adjust the orientation of the display surface 31 around the virtual adjustment axis Ax by the difference in curvature between the left and right sides. Therefore, the condensing range of the external light reflected light OLr reflected by the display surface 31 can be excluded from the iris center CEL (see FIG. 9). According to the above, since the same effect as that of the first embodiment is obtained, even in the display device 300 that employs the EL display 30 that displays information on the curved display surface 31, the visibility is deteriorated by the external light OL. It can be reduced.

In addition, in the third embodiment, the orientation of the display surface 31 is changed by the adjustment mechanism 340 that individually adjusts the curvature of the display surface 31 at a plurality of locations. Even if such an adjustment mechanism 340 is adopted, a virtual adjustment axis Ax can be set on the EL display 30. Based on the above, it is possible to effectively utilize the characteristics of the flexible EL display 30 to obtain the effect of reducing the deterioration of visibility.

Further, if the curvatures are changed on the left and right sides of the display surface 31 as in the third embodiment, the resonance frequencies at each part of the display surface 31 have different values. Therefore, even if the sheet-shaped EL display 30 is used, resonance of the EL display 30 due to vehicle vibration or the like can be prevented.

(Other embodiments)
Although the plurality of embodiments of the present disclosure have been described above, the present disclosure is not construed as being limited to the above embodiments, and is applied to various embodiments and combinations without departing from the gist of the present disclosure. can do.

In the display device 400 according to the first modification of the first embodiment, the adjustment mechanism 440 sets a plurality (two) adjustment axes Ax on the EL display 30 as shown in FIG. One of the adjustment shafts Ax is substantially the same as that of the first embodiment, and is defined as a posture along the yaw axis of the vehicle A. The other adjustment shaft Ax is defined as a posture along the pitch axis of the vehicle A, and is located near the lower edge of the display surface 31. The movable holding portion 41 that holds the EL display 30 in the adjusting mechanism 440 is driven by two attitude control motors, and can change the orientation of the display surface 31 in the left-right direction and the up-down direction. The above adjustment mechanism 440 can shift the reflection position and the reflection posture of the display surface 31 from the reference position and the posture at a solid angle in the oblique direction by the complex movement around the two adjustment axes Ax. Therefore, even in the first modification, the optical axis of the reflected external light can be removed from the center of the irips.

In the modified example 2 of the second embodiment, the adjusting mechanism has the first adjusting shaft of the posture along the yaw axis and the second adjusting shaft of the posture along the pitch axis, as in the modified example 1 of the above. , Is set to EL display.

In the third modification of the third embodiment, the adjustment mechanism defines a virtual adjustment axis extending in the horizontal direction on the EL display. In the third modification, the display surface is used in a concave cylindrical state having a curvature in the horizontal direction. Each curvature adjusting unit adjusts the orientation of the display surface in the vertical direction by individually expanding and contracting the upper edge and the lower edge of the display surface.

In the modified example 4 of the above embodiment, one of the two adjustment shafts is an actual adjustment shaft defined by the movable holding portion, and the other is a virtual adjustment shaft defined by the curvature adjustment portion. As in the above modified examples 1 to 4, the number, position, posture, and the like of the adjustment axes set in the EL display can be changed as appropriate. For example, the posture adjustment axis along the roll axis of the vehicle may be set as one of the plurality of adjustment axes.

In the fifth modification of the above embodiment, the display surface is a convex cylindrical curved state having a curvature in the vertical direction, and is used for information display. Further, in the modified example 6 of the above embodiment, the display surface is used for information display in a convex cylindrical curved state having a curvature in the horizontal direction. Such a display surface may have a curvature in both the vertical direction and the horizontal direction.

In the modified example 7 of the above embodiment, the mechanism control unit acquires the position information of the driver's current eye point from the driver status monitor mounted on the vehicle). The mechanism control unit controls the adjustment mechanism so that the optical axis of the reflected external light is not only deviated from the center of the eye lip, but also deviated from the current eye point.

In the modified example 8 of the above embodiment, the attitude control motor is omitted from the adjustment mechanism. In addition, the display controller does not have a functional unit corresponding to an external light grasping unit and a mechanism control unit. The adjustment mechanism of the modified example 8 enables a user such as a driver to perform manual adjustment to change the orientation of the display surface around the adjustment axis. Even in the above modification 8, it is possible to deviate the focusing range of the external light reflected light from the center of the irips.

The storage mechanism according to the modified example 9 of the first embodiment stores the EL display in the storage space by tilting the EL display toward the front side (rear of the vehicle). Further, the storage mechanism according to the modified example 10 of the first embodiment stores the EL display in the storage space by tilting the EL display to the back side (front of the vehicle). As in the above modifications 9 and 10, the operating mode of the mechanism for accommodating the EL display in the accommodation chamber can be changed as appropriate. Then, also in these modified examples 9 and 10, control is performed to remove the condensing range of the external light reflected light from the center of the irips in the movable locus in the middle of rising.

In the modified example 11 of the above embodiment, the display control unit does not perform display correction according to the orientation of the display surface. Further, the display control unit of the modified example 12 only corrects the shape of the image according to the orientation of the display surface, and does not perform the luminance correction and the color correction. Further, the display control unit of the modification 13 corrects the luminance correction and the color correction according to the orientation of the display surface. As in the above modified examples 12 and 13, the display control unit may correct only one or two of the shape of the image displayed on the display surface, the emission brightness, and the emission color.

The installation position of the EL display in the vehicle interior can be changed as appropriate. For example, the EL display may be used as an indicator of an electronic mirror system that replaces the functions of the rearview mirror and the side mirror. Further, the EL display may be a display installed on a center console or the like. Further, a curved display having a configuration different from that of the EL display, for example, a micro LED display or the like, can be adopted as a curved display in the display device.

The display surface of the EL display may be provided with a reflection suppression configuration that reduces the reflection of external light. The reflection suppression configuration is, for example, a low reflection fine structure, a low reflection multilayer film structure, a wedge-shaped film having a variable reflection angle, or the like. Further, a configuration for adjusting the direction of light emitted from the light emitting element, specifically, a light control filter of a blind method or a resin orientation angle selection method, a polarizing plate, or the like may be provided on the display surface. Further, the detailed structure of the adjusting mechanism may be defined in consideration of the shapes of the sunroof, the front windshield, the shade band, and the like so that the optical axis of the reflected external light can be reliably removed from the center of the eye lip.

The processor used in the display controller is a processing unit including one or a plurality of CPUs (Central Processing Units). Such a processor may be configured to include a GPU (Graphics Processing Unit), an FPGA (Field-Programmable Gate Array), an IP core having other dedicated functions, and the like in addition to the CPU.

Various non-transitory tangible storage media such as flash memory and hard disk can be adopted as the memory device for storing each control program and parameters. The form of such a storage medium may also be changed as appropriate. For example, the storage medium may be in the form of a memory card or the like, and may be inserted into a slot portion provided in an in-vehicle ECU and electrically connected to a control circuit.

The control unit and its method described in the present disclosure may be realized by a dedicated computer constituting a processor programmed to execute one or a plurality of functions embodied by a computer program. Alternatively, the apparatus and method thereof described in the present disclosure may be realized by a dedicated hardware logic circuit. Alternatively, the apparatus and method thereof described in the present disclosure may be realized by one or more dedicated computers configured by a combination of a processor that executes a computer program and one or more hardware logic circuits. Further, the computer program may be stored in a computer-readable non-transitional tangible recording medium as an instruction executed by the computer.

A vehicle, Ax adjustment shaft, EyL eye lip, CSE (eye lip) center, OL outside light, 4 containment chamber, 30 EL display (curvature display), 31 display surface, 39 movable base (base part), 40,340 , 440 adjustment mechanism, 41 movable holding unit, 343, 344 curvature adjustment unit, 50 storage mechanism, 71 external light grasping unit, 72 mechanism control unit (adjustment execution unit), 73 display control unit, 100, 200, 300, 400 display Device

Claims (6)

A display device used in a vehicle (A) that displays information toward a predetermined eye lip (EyL) for the driver's seat of the vehicle.
A curved display (30) that displays information on the curved display surface (31), and
An adjustment axis (Ax) for adjusting the orientation of the display surface is set on the curved display so that the focusing range of the external light (OL) reflected on the display surface deviates from the center (CEL) of the irips. , An adjustment mechanism (40, 340, 440) that makes it possible to change the orientation of the display surface around the adjustment axis.
An external light grasping unit (71) for grasping the state of external light incident on the display surface, and
Based on the condition of the external light grasped by the external light grasping unit, the adjustment executing unit (72) that changes the orientation of the display surface so that the light collecting range is far from the center of the eye lip.
A storage mechanism that allows the curved display to be stored in the storage room (4) partitioned by the vehicle, and moves the curved display from the storage state stored in the storage room to the activated state for displaying information. and 50), with a,
The adjustment execution unit, said at stroke of a curved display said stored state until the start state, display the focusing range that controls the adjustment mechanism so that off-center of the Airipusu device. A display device used in a vehicle (A) that displays information toward a predetermined eye lip (EyL) for the driver's seat of the vehicle.
A curved display (30) that displays information on the curved display surface (31), and
An adjustment axis (Ax) for adjusting the orientation of the display surface is set on the curved display so that the focusing range of the external light (OL) reflected on the display surface deviates from the center (CEL) of the irips. , An adjustment mechanism (40, 340, 440) that can change the orientation of the display surface around the adjustment axis is provided .
The adjusting mechanism has a plurality of curvature adjusting portions (343, 344) that individually adjust the curvature of the curvature of the display surface at different positions.
The plurality of the curvature adjustment unit, a virtual of the adjusting shaft set Ru display device to the curved display. An external light grasping unit (71) for grasping the state of external light incident on the display surface, and
Based on the condition of the external light grasped by the external light grasping unit, the adjustment executing unit (72) that changes the orientation of the display surface so that the light collecting range is far from the center of the eye lip.
The display device according to claim 2 , further comprising. A storage mechanism that allows the curved display to be stored in the storage room (4) partitioned by the vehicle, and moves the curved display from the storage state stored in the storage room to the activated state for displaying information. 50), with
The adjustment execution unit, in the movement stroke to the curved display is the active state from the stored state, according to claim 3, wherein the condensing range to control the adjustment mechanism to deviate from a center of the Airipusu Display device. The adjusting mechanism includes a movable holding portion (41) that rotatably supports the curved display with respect to a base portion (39) held by the vehicle and sets the adjusting axis on the curved display. The display device according to any one of claims 1 to 4. Claims 1 to 5 further include a display control unit (73) that corrects at least one of the shape, emission brightness, and emission color of an image displayed on the display surface according to a change in the orientation of the display surface. The display device according to any one of the above.

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