JP2015062002A - Display device for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device for a vehicle that displays a pointer type meter image on a screen with a concave and convex, and can easily suppress distortion of a pointer image.SOLUTION: A display device for a vehicle includes a projector that emits display light of a meter image D showing vehicle information, and a screen 30 that has the display light projected thereon to display the image. The screen 30 includes a spherical part 31 that forms a spherical surface raised on the front side or rear side in a direction in which the meter image D is visually recognized. The meter image D displayed on the screen 30 includes a pointer image D11 showing a rotating pointer, and a scale image D21 showing a scale pointed by the pointer image D11, and the pointer image D11 is displayed on the spherical portion 31.

Description

  The present invention relates to a vehicle display device that displays an image representing vehicle information on a screen by projecting display light emitted from a projector onto the screen.

  Patent Document 1 discloses a display device including a projector that emits display light of an image representing vehicle information such as a vehicle speed, and a screen that displays the image by projecting the emitted display light. . The screen according to this display device is formed in an uneven shape in the direction in which the image is visually recognized, so that the image is visually recognized in three dimensions.

JP 2007-326419 A

  Now, the present inventor has studied to make the pointer-type meter visually visible by displaying an image of the pointer-type meter on the screen. However, since the projections and depressions are formed on the screen, when the pointer image is rotated and displayed on the screen, the position where the pointer image crosses the projections and depressions changes. For this reason, the pointer image is displayed in a distorted form with rotation. Although it is theoretically possible to eliminate the distortion by correcting the display light according to the rotation position, such correction is not practical because it requires extremely complicated processing.

  The present invention has been made in view of the above problems, and an object thereof is to provide a vehicle display device that can easily suppress distortion of a pointer image when displaying a pointer-type meter image on an uneven screen. It is in.

  The present invention employs the following technical means to achieve the above object. It should be noted that the reference numerals in parentheses described in the claims and in this section indicate the correspondence with the specific means described in the embodiments described later as one aspect, and the technical scope of the present invention It is not limited.

  One of the disclosed inventions is a projector (20) that emits display light (P) of a meter image (D, Da, Db) representing vehicle information, and a meter image is displayed by projecting the display light. A screen (30), and the screen has a spherical portion (31) that forms a spherical surface that protrudes toward the front side or the back side in the direction in which the meter image is visually recognized. The pointer image (D11) shown and the scale image (D21) showing the scale pointed by the pointer image are included, and the pointer image is displayed on the spherical surface.

  According to this, the screen has a spherical portion raised in the viewing direction, and a pointer image is displayed on the spherical portion. For this reason, it is possible to suppress the distortion of light corresponding to the pointer image from the display light projected on the screen from changing according to the rotation position of the pointer image. Therefore, it is possible to easily suppress the pointer image from being displayed in a distorted shape with rotation.

BRIEF DESCRIPTION OF THE DRAWINGS Sectional drawing which shows typically a whole structure about the display apparatus for vehicles which concerns on 1st Embodiment of this invention. The front view which shows the one aspect | mode of the meter image displayed on the screen of FIG. Sectional drawing which follows the III-III line | wire of FIG. The front view which shows how to make the gradation display of a display board image in 1st Embodiment. The front view which shows how to make the gradation display of a display board image in 2nd Embodiment of this invention. The front view which shows how to make the gradation display of a display board image in 3rd Embodiment of this invention. The front view which shows a mode that the gradation display of a display board image changes in 3rd Embodiment.

  A plurality of modes for carrying out the invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Not only combinations of parts that clearly show that combinations are possible in each embodiment, but also combinations of the embodiments even if they are not explicitly stated unless there is a problem with the combination. Is also possible.

(First embodiment)
The instrument panel 10 shown in FIG. 1 is disposed below the front windshield in the vehicle interior. On the back side of the translucent cover 11 attached to the opening 10a of the instrument panel 10, a vehicle display device that will be described in detail later is installed. In addition, the arrow which shows the up-down front-back direction in FIG. 1 shows the up-down front-back direction of a vehicle in the state in which the display apparatus for vehicles was installed in the instrument panel 10. FIG.

  The vehicular display device includes a projector 20, a screen 30, and a reflecting mirror 40 described below. The projector 20 emits display light P of an image representing vehicle information. Specific examples of the “vehicle information” represented by the above image include vehicle speed, engine rotation speed, automatic transmission shift range, fuel remaining amount, engine coolant temperature, various warning information, and the like.

  An electronic control device (hereinafter referred to as meter ECU 12) is connected to be communicable with another electronic control device. Meter ECU12 acquires the above-mentioned vehicle information which other electronic control units computed based on various sensors by communication. The meter ECU 12 controls the operation of the projector 20 based on the acquired vehicle information. For example, the meter ECU 12 transmits vehicle speed information acquired sequentially every predetermined time to the projector 20. The projector 20 emits display light P of an image that displays the vehicle speed information transmitted from the meter ECU 12.

  The projector 20 includes a magnifying lens 21, a display light generation device 22, and a light source (not shown) described below. The display light generating device 22 transmits light from the light source to the liquid crystal panel and generates display light representing a desired image. Alternatively, the light of the light source is transmitted through a color filter that rotates at high speed to generate display light representing a desired image. The image light generated by the display light generation device 22 is expanded by the magnifying lens 21 and then emitted from the projector 20 as the display light P.

  The reflecting mirror 40 reflects the display light P emitted from the projector 20 toward the screen 30. In the example of FIG. 1, the reflecting surface of the reflecting mirror 40 has a convex shape, and the display light P is magnified and reflected. The display light Q reflected by the reflecting mirror 40 is transmitted from the opposite side (back side) to the near side of the screen 30 with respect to the viewer M. The display light R transmitted through the screen 30 passes through the translucent cover 11 and enters the eyes of the user who is the viewer M. That is, the image displayed on the screen 30 is visually recognized by the user by the projection of the display light Q on the screen 30.

  The screen 30 is a resin-made plate having translucency, and has a plate shape with a uniform thickness on which the spherical portion 31 is formed. As shown in FIG. 2, the screen 30 has a circular shape when viewed from the viewer M side, and the spherical portion 31 is located at the center of the circular screen 30. The spherical portion 31 forms a spherical surface with a constant curvature. The screen 30 has a shape having a bottom portion 32, an inclined portion 33, and an outer peripheral portion 34 described below in addition to the spherical portion 31. Further, when viewed from the viewer M side, the spherical surface portion 31 has a circular shape, and the bottom portion 32, the inclined portion 33, and the outer peripheral portion 34 have an annular shape. The inner periphery of the bottom portion 32 is connected to the outer periphery of the spherical portion 31, the inner periphery of the inclined portion 33 is connected to the outer periphery of the bottom portion 32, and the inner periphery of the outer peripheral portion 34 is connected to the outer periphery of the inclined portion 33.

  As illustrated in FIG. 3, the spherical surface portion 31 forms a spherical shape that protrudes toward the viewer M and curves in a direction that protrudes toward the viewer M. A spherical vertex 31b is located at the center of the spherical surface portion 31 as viewed from the viewer M side. The virtual plane in contact with the vertex 31b is perpendicular to the viewing direction (up and down direction in FIG. 3). Therefore, the further away from the vertex 31b of the spherical portion 31, the greater the inclination angle with respect to the virtual surface. In the following description, the portion of the spherical surface portion 31 where the inclination angle is a predetermined angle (for example, 45 degrees) or more is referred to as a steep slope portion 31a.

  The bottom portion 32 has an annular shape extending in the radial direction from the outer peripheral end of the spherical portion 31 and forms a plate surface parallel to the virtual surface. The inclined portion 33 has an annular shape extending in the radial direction from the outer peripheral end of the bottom portion 32, and forms a flat inclined surface that gradually rises toward the viewer M at a certain angle with respect to the virtual surface. The outer peripheral portion 34 has an annular shape extending in the radial direction from the outer peripheral end of the inclined portion 33, and forms a plate surface parallel to the virtual surface. The apex 31 b of the spherical surface portion 31 is positioned on the viewer M side with respect to the outer peripheral portion 34, and the steep slope portion 31 a of the spherical surface portion 31 is positioned on the opposite side of the viewer M with respect to the outer peripheral portion 34.

  As shown in FIG. 2, the image displayed on the screen 30 is an image (meter image D) showing a meter configured by combining a plurality of components. The “plural components” include a display plate D10, a scale plate D20, decorative rings D30 and D40, a pointer D11, and a boss D12 described below. These display board D10, scale board D20, decoration rings D30 and D40, pointer D11 and boss D12 are not actual parts but images (part images).

  The display board D10 is displayed on the spherical portion 31 together with a plurality of numbers D13. Further, the pointer D11 and the boss D12 are also displayed on the spherical surface portion 31. The display panel D10 has a circular shape along the outer shape of the spherical surface portion 31, and a circular boss D12 is displayed at the center of the display panel D10. The pointer D11 has a shape extending from the boss D12 in the radial direction of the display plate D10, and is displayed as a moving image so as to rotate on the display plate D10 around the boss D12. The number D13 is a still image displayed on the steep slope 31a and representing the vehicle speed. The pointer D11, the boss D12, and the number D13 are displayed in a color different from that of the display board D10.

  As shown in FIG. 4, the display board D10 is displayed in gradation so that the luminance gradually changes from the vertex 31b to the outer peripheral edge. Specifically, as indicated by a two-dot chain line arrow in FIG. 2, the luminance is changed radially from the apex 31b, and the closer to the outer peripheral end, the higher the luminance is displayed. Note that “luminance” in this specification is a value obtained by dividing the luminous intensity by the light source area. The “luminosity” is a value obtained by integrating a value obtained by multiplying the radiation intensity for each wavelength by the relative visibility for each wavelength. As an example of the relative luminous efficiency, there is a standard luminous efficiency determined by the International Metrology General Assembly.

  In other words, the display board D10 is displayed in gradation so that the luminance gradually increases as the distance from the predetermined point of the spherical surface portion 31 increases. And the said predetermined point is located in the rotation center (namely, vertex 31b) of the pointer | guide D11, and is set to one place. 2 and FIG. 3 are phantom lines extending in the circumferential direction around the apex 31b on the surface of the spherical portion 31. In FIG. These imaginary lines K1, K2, and K3 are circular with the vertex 31b as the center, and can be said to be imaginary contour lines in which the raised height of the spherical surface portion 31 is the same. The display board D10 is displayed in gradation so as to have the same luminance on the same virtual lines K1, K2, and K3.

  In addition, while the display board D10 is displayed in gradation, the pointer D11 and the boss D12 are not displayed in gradation but are displayed with a single luminance. Thereby, it is possible to make an illusion that the pointer D11 and the boss D12 are parts different from the display panel D10.

  The display board D10 is a background image representing the background of the pointer D11, while the numeral D13 is an ideographic image having a certain meaning. For example, the number with the symbol D13 is a three-digit number and can be said to be an ideographic image formed by combining a plurality of element images D13a, D13b, and D13c (see FIG. 2). That is, although the three-digit number with the symbol D13 represents “140”, the element image D13a representing “1”, the element image D13b representing “4”, and the element image D13c representing “0” Are arranged in order. Note that the length in the direction in which the plurality of element images D13a, D13b, D13c are arranged in the ideographic image (that is, the horizontal dimension of the number D13) is longer than the vertical dimension of the number D13.

  The plurality of element images D13a, D13b, and D13c are arranged side by side in a direction that intersects the direction that goes down the steep slope portion 31a. The descending direction is a direction extending in the radial direction from the apex 31 b of the spherical portion 31 along the surface of the spherical portion 31. The plurality of element images D13a, D13b, D13c are arranged side by side on the virtual line K1. Therefore, it can be said that the direction in which the plurality of element images D13a, D13b, and D13c are arranged is parallel to the rotational circumferential direction of the pointer D11.

  Returning to the description of FIG. 2, the scale plate D20 is displayed on the bottom 32 together with the scale D21. The scale plate D20 has an annular shape along the inner periphery and the outer periphery of the bottom portion 32. The scale D21 is displayed at a position corresponding to each of the plurality of numbers D13. The scale plate D20 is a scale background image representing the background of the scale D21. The scale plate D20 is a color different from the scale D21. The numbers D13 and the scales D21 described above are also images, not actual printed matter. Then, the pointer D11 displayed in rotation rotates to indicate the scale D21. Thereby, the meter image D represents the vehicle speed which is vehicle information.

  The decoration rings D30 and D40 are displayed on the inclined portion 33 and the outer peripheral portion 34. The decorative ring D30 displayed on the inclined portion 33 is displayed in gradation so that the luminance gradually changes from the inner peripheral end to the outer peripheral end. The decorative ring D40 displayed on the outer peripheral portion 34 is displayed with the same luminance as the outer peripheral end of the decorative ring D30.

  A contour line image L1 representing the contour line of the display plate D10 is displayed on a portion of the screen 30 positioned on the outer edge of the spherical surface portion 31, that is, a boundary portion 30L between the spherical surface portion 31 and the bottom portion 32. The contour image L1 is set to a color different from that of the spherical surface portion 31 and the bottom portion 32. The outline image L1 is an image of a line set to such a width that the viewer can recognize the presence of the outline image L1.

  In short, the vehicle display device of the present embodiment described above includes the features listed below. And the effect demonstrated below is exhibited by each of those characteristics.

<Feature 1>
A spherical portion 31 bulging toward the near side in the viewing direction (that is, the viewer side) is formed on the screen 30, and a pointer image D <b> 11 is displayed on the spherical portion 31. Therefore, it can suppress that the distortion condition of the light corresponding to the pointer | guide image D11 among the display lights projected on the screen 30 changes according to a rotation position. Therefore, it is possible to easily suppress the shape and length of the pointer image D11 from changing according to the rotation position.

  Here, contrary to the present embodiment, the bent portion on the screen 30, that is, the boundary portion between the spherical surface portion 31 and the bottom portion 32, the boundary portion between the bottom portion 32 and the inclined portion 33, and the boundary portion between the inclined portion 33 and the outer peripheral portion 34 are straddled. When the pointer image D11 is displayed as described above, the following problem occurs. That is, when the screen 30 is viewed from the front, the pointer image D11 looks like a shape extending straight in the radial direction, but when the screen 30 is viewed from an oblique direction, the pointer image D11 is at the bent portion. Appears to be bent.

  In the present embodiment in view of this point, the display range of the pointer image D11 is limited within the spherical portion 31. Therefore, when the screen 30 is viewed from an oblique direction, the pointer image D11 may appear to be curved, but it does not appear to be bent. In this way, it is possible to suppress the appearance of the pointer image D11 from changing according to the viewing direction.

<Feature 2>
The meter image D includes a background image (that is, a display board D10) displayed on the spherical portion 31 and representing the background of the pointer image D11. The background image is displayed in gradation so that the luminance gradually changes as the distance from the predetermined point (that is, the vertex 31b) of the spherical surface portion 31 increases.

  According to this, it is possible to make an illusion that the spherical surface portion 31 is illuminated by the light from the virtual light source and that the spherical surface portion 31 has a shadow. Therefore, it is emphasized that the spherical portion 31 is raised on the near side or the far side, and it can be promoted that the spherical portion 31 appears to swell three-dimensionally. Therefore, the stereoscopic effect of the virtual meter expressed by the meter image D can be realistically expressed, and the user can have an illusion as if the meter actually exists.

<Feature 3>
The predetermined point related to the gradation display is located at the rotation center of the pointer image D11. According to this, the spherical surface portion 31 appears to swell three-dimensionally toward the front side or the back side as compared with the case where the predetermined points 31c and 31d are located at positions deviated from the rotation center as shown in FIGS. The above effects can be promoted.

<Feature 4>
A contour line image L <b> 1 representing the contour line of the spherical surface portion 31 is displayed on a portion of the screen 30 positioned at the outer edge of the spherical surface portion 31. According to this, in the screen 30, the part located in the outer edge of the spherical surface part 31 comes to be visually recognized conspicuously. For this reason, it is possible to promote the illusion that the parts of the meter represented by the background image (that is, the display board D10) exist.

<Feature 5>
The spherical portion 31 is formed in a shape with a constant curvature. Therefore, even if the rotational position of the pointer D11 changes, the shape and length of the pointer D11 do not change. Therefore, it can be visually recognized without changing the shape and length of the pointer D11 without correcting the display light.

<Feature 6>
The meter image D includes an ideographic image (that is, an image of the number D13) configured by combining a plurality of element images D13a, D13b, and D13c representing numbers, characters, or designs. This ideographic image is displayed on the steep slope portion 31a of the spherical portion 31, and the plurality of element images D13a, D13b, and D13c are arranged side by side in a direction intersecting with the direction descending the steep slope portion 31a (specifically, virtual Arranged side by side on the line K1). The technical significance of this configuration will be described below.

  The display light P emitted from the projector 20 is magnified by the magnifying lens 21, and the display light P is further magnified by the reflecting mirror 40. Therefore, the display light Q projected on the screen 30 advances while expanding. Therefore, as the optical path length from the projector 20 to the screen 30 is longer, the degree of enlargement of the display light Q becomes larger and the image displayed on the screen 30 becomes larger. Therefore, when the plurality of element images D13a, D13b, and D13c are arranged side by side in the direction (that is, the radial direction) down the steep slope portion 31a, the optical path length of each element image is represented by reference sign Q1 in FIG. It differs as shown in Q2 and Q3.

  Specifically, when the element images D13a, D13b, and D13c are arranged on three different virtual lines K1, K2, and K3 (see FIG. 3), the optical path length Q1 is higher toward the upper side of the steep slope portion 31a. , Q2 and Q3 become longer. The element image is enlarged and displayed as the optical path length is longer. As a result, the ideographic image (that is, the image of the number D13) is displayed distorted.

  According to this embodiment in view of this point, the plurality of element images D13a, D13b, and D13c are arranged side by side in the circumferential direction of the steep slope portion 31a. That is, the plurality of element images D13a, D13b, and D13c are arranged on the same contour line (virtual line K1). Therefore, since it can suppress that the optical path length of several element image D13a, D13b, D13c mutually differs, it can suppress that distortion arises in the number D13. Therefore, while the spherical portion 31 is formed on the screen 30 so that the image on the display plate D10 can be viewed three-dimensionally, it is possible to suppress deterioration in legibility of the number D13 resulting from the formation of the spherical portion 31.

<Feature 7>
Furthermore, in the present embodiment, the direction in which the plurality of element images D13a, D13b, and D13c are arranged is parallel to the rotation direction of the pointer image D11. Therefore, as a result of arranging a plurality of element images D13a, D13b, and D13c in a direction intersecting with the direction of going down the steep slope portion 31a, even if the orientation of the ideographic image is tilted when viewed from the viewer M, the uncomfortable feeling given to the viewer M Can be reduced. For example, the number D13 shown in FIG. 2 is rotated by 90 degrees and tilted when viewed from the viewer M. However, since the direction of rotation of the pointer D11 and the direction of the number D13 match, the discomfort given to the viewer M can be reduced. Decrease in legibility of the number D13 (ideographic image) can be suppressed.

(Second Embodiment)
In the display board D10 according to the first embodiment, when a gradation is displayed starting from a predetermined point, the predetermined point is set as the rotation center (that is, the vertex 31b) of the pointer image D11. On the other hand, the display board D10a of the meter image Da according to the present embodiment is at a position shifted from the rotation center of the pointer image D11 as shown in FIG. In the example of FIG. 6, the predetermined point 31c is located in the lower right part on the display board D10b. Then, as indicated by a two-dot chain line arrow in FIG. 5, gradation is displayed so that the luminance gradually decreases as the distance from the predetermined point 31c increases. In addition, the entire display panel D10b is displayed in gradation.

  According to the present embodiment, it is possible to make the illusion that the spherical portion 31 is illuminated by the light from the virtual light source and that the spherical portion 31 has a shadow. Therefore, it is emphasized that the spherical portion 31 is raised on the near side or the far side, and it can be promoted that the spherical portion 31 appears to swell three-dimensionally. Therefore, the stereoscopic effect of the virtual meter expressed by the meter image Da can be expressed realistically, and the user can have an illusion as if the meter actually exists.

(Third embodiment)
The gradation display of the display board D10b image according to the present embodiment changes so that the predetermined points 31c and 31d move as shown in FIGS. Specifically, the predetermined points 31c and 31d rotate around the rotation center of the pointer image D11.

  Furthermore, the meter image Db according to the present embodiment includes a caution display image D14 (see FIG. 7) that alerts the vehicle driver, and causes the change when the caution display image D14 is displayed. The caution display image D14 is displayed at the central portion of the spherical portion 31.

  For example, when a vehicle is equipped with a system that detects the presence of an obstacle such as another vehicle or a pedestrian in front of the host vehicle, the system drives that attention should be paid to the front based on the detection. It is determined whether or not to alert the person. If it is determined to be aroused, the system transmits a warning command signal to the meter ECU 12. Meter ECU12 transmits a display command signal to projector 20, so that caution display picture D14 may be displayed, when a caution calling command signal is received. When the display command signal is received, the projector 20 generates and emits the display light of the caution display image D14 by the display light generation device 22, and displays the gradation on the display board D10b so that the predetermined points 31c and 31d rotate. To change.

  In the second embodiment, the entire display board D10b is displayed in gradation. On the other hand, in the present embodiment, as indicated by a two-dot chain line in FIGS. 6 and 7, the display plate D10b is partially gradation-displayed for a predetermined range centered on the predetermined points 31c and 31d.

  As described above, according to the present embodiment, the gradation display of the background image (that is, the display board D10b) changes so that the predetermined points 31c and 31d that are the starting points of the gradation move. Therefore, it is possible to make an illusion that the position of the virtual light source described in the second embodiment moves. Therefore, it is possible to promote the illusion that the meter is realistically expressed as if it existed.

  Furthermore, the meter image Db according to the present embodiment includes a caution display image D14 that alerts the vehicle driver. When the caution display image D14 is displayed, the gradation of the background image (that is, the display board D10b) is displayed. The above change is caused in the display. Here, if the gradation display of the background image is changed so that the predetermined points 31c and 31d move, the user is attracted to the display change. Therefore, according to the present embodiment in which the display change is caused when the attention display image D14 that alerts the vehicle driver is displayed, the alerting to the vehicle driver can be promoted.

(Other embodiments)
The present invention is not limited to the description of the above embodiment, and may be modified as follows. Moreover, you may make it combine the characteristic structure of each embodiment arbitrarily, respectively.

  In the embodiment shown in FIG. 3, the spherical portion 31 of the screen 30 that displays the pointer D11 has a shape with a constant curvature. On the other hand, a spherical portion having a shape whose curvature is not constant may be adopted, and the pointer D11 may be displayed on the spherical portion.

  In the embodiment shown in FIG. 3, the spherical surface portion 31 has a shape protruding to the near side, but may be a shape protruding to the back side.

  In the embodiment shown in FIGS. 4 to 7, the spherical portion 31 is displayed in gradation so that the luminance gradually decreases as the distance from the predetermined point 31c increases. Conversely, the gradation is increased so that the luminance gradually increases. It may be displayed.

  In the embodiment shown in FIGS. 4 to 7, the predetermined points 31b, 31c, and 31d that are the starting points of the gradation display are set at one place, but the gradation display may be set at a plurality of places.

  In the embodiment shown in FIGS. 4 to 7, the background images D10, D10a, and D10b of the pointer D11 are displayed in gradation. However, the gradation display may be abolished and displayed with a single luminance. The luminance may be changed step by step.

  In the embodiment shown in FIGS. 4 to 7, the spherical portion 31 is circular in the front view of the screen 30. On the other hand, the spherical surface part 31 may have a shape (for example, a semicircular shape) in which a part of a circular shape is cut out from the outer peripheral side.

  In the embodiment shown in FIGS. 4 to 7, the pointer D11 and the boss D12 are displayed with a single luminance, but may be displayed in gradation or may be displayed with the luminance changed stepwise.

  In the embodiment shown in FIGS. 4 to 7, the scale D <b> 21 is displayed on the flat bottom portion 32, so that the visibility of the scale D <b> 21 is improved as compared with the case where the scale D <b> 31 is displayed on the steep slope 31 a. . On the other hand, the scale D21 may be displayed on the spherical portion 31. In the embodiment shown in FIGS. 4 to 7, the number D <b> 13 is displayed on the spherical portion 31, but the number D <b> 13 may be displayed on a portion other than the spherical portion 31 (for example, the bottom portion 32).

  -Element image D13a, D13b, D13c which concerns on the said embodiment is arranged side by side in the direction orthogonal to the direction which goes down steep slope part 31a. However, the arrangement direction of the element images according to the present invention is not limited to being orthogonal to the direction going down the steep slope portion 31a, but may be arranged in a direction intersecting with the direction going down the steep slope portion 31a. However, it is preferable to arrange them in orthogonal directions because distortion can be suppressed to the maximum.

  In the example shown in FIG. 2, the ideographic image D13 is a number, and the numbers of each digit constituting the number are element images D13a, D13b, and D13c. On the other hand, the ideographic image is a character, and each character constituting the character may be an element image. For example, it is only necessary that each alphabet constituting the character “CHARGE” is an elemental image, and each alphabet is arranged along the one-dot chain line K1 (that is, the contour line) in FIG. Alternatively, the ideographic image may be a symbol composed of a plurality of element images, for example, a symbol representing weather, a symbol representing a blowing state by an air conditioner, a symbol representing an abnormal state of the vehicle, or the like. In addition, an ideographic image may be configured by combining these numbers, characters, and designs.

  In the embodiment shown in FIG. 1, the vehicle is configured such that the display light Q is incident on the screen 30 from the opposite side of the viewer M so that the display light Q passes through the screen 30 and enters the viewer M's eyes. The display device for an apparatus is comprised. On the other hand, the display light may be incident on the screen 30 from the viewer M side, and the display light may be reflected from the screen 30 to enter the eyes of the viewer M.

  DESCRIPTION OF SYMBOLS 20 ... Projector, 30 ... Screen, 31 ... Spherical surface part, D ... Meter image (image showing vehicle information), D11 ... Pointer (pointer image), D10 ... Display board (background board image), P ... Display light.

Claims (6)

A projector (20) for emitting display light (P) of a meter image (D, Da, Db) representing vehicle information;
A screen (30) for displaying the meter image by projecting the display light;
With
The screen has a spherical surface portion (31) that forms a spherical surface raised on the near side or the far side in the direction in which the meter image is visually recognized,
The meter image includes a pointer image (D11) representing a rotating pointer, and a scale image (D21) representing a scale pointed to by the pointer image,
The display device for vehicles, wherein the pointer image is displayed on the spherical portion. The meter image includes a background image (D10, D10a, D10b, D10c) displayed on the spherical portion and representing the background of the pointer image,
2. The vehicle display according to claim 1, wherein the background image is displayed in gradation so that the luminance gradually increases or decreases as the distance from the predetermined point (31 b, 31 c, 31 d) of the spherical surface portion increases. apparatus.   The vehicle display device according to claim 2, wherein the predetermined point (31b) is located at a rotation center of the pointer image.   4. The vehicle display device according to claim 2, wherein the gradation display of the background image changes so that the predetermined point moves. The image displayed on the screen includes a caution display image (D14) for alerting the vehicle driver,
The vehicle display device according to claim 4, wherein when the caution display image is displayed, the change is caused in the gradation display of the background image.   The contour image (L1) representing the contour of the spherical portion is displayed on a portion of the screen located at the outer edge of the spherical portion. The display apparatus for vehicles as described in one.

Images