JP2015043012A - Head-up display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a head-up display device which is compact and capable of generating high-quality images as virtual images.SOLUTION: A head-up display device generates a virtual image of an image to be viewed by a driver 7 of a vehicle 2 by projecting the image from a projector 4 onto a first screen 20 and a second screen 21 via a first projection lens 16 and a second projection lens 17, respectively, and reflecting the images projected on the first screen 20 and the second screen 21 onto a windscreen 6 of the vehicle 2 for the driver 7 to see. The head-up display is configured such that distance from the driver to the virtual image is adjusted by moving the second screen 21 along an optical axis, and that the movement of the second screen 21 is accompanied by movement of the second projection lens 17 in a direction opposite the movement of the second screen 21 such that the image projected by the second projection lens 17 is kept focused on the second screen 21.

Description

  The present invention relates to a head-up display device that can be mounted on a moving body and generates various images that are visually recognized by a passenger of the moving body.

  Conventionally, various means have been used as information providing means for providing driving information such as route guidance and obstacle warnings to passengers of moving bodies such as vehicles. For example, display on a liquid crystal display installed on a moving body, sound output from a speaker, and the like. In recent years, as one of such information providing means, there is a head-up display device (hereinafter referred to as HUD).

  Here, for example, a HUD installed on a vehicle as a moving body is located in front of a vehicle window (for example, a front window) as seen from a vehicle occupant, as described in JP-A-2009-288388. It is possible to generate a virtual image superimposed on the foreground of the front visual field. As a result, the occupant can reduce the line-of-sight movement as much as possible when visually confirming the driving information, and can further reduce the burden during driving.

JP 2009-288388 A (page 3-5, FIG. 2)

  Here, in order to reduce the burden on the vehicle occupant during driving, it is important to appropriately set the position (more specifically, the distance from the occupant to the virtual image) where the virtual image is generated. For example, in order to generate a virtual image of a warning for an obstacle, it is desirable to generate a virtual image at a position where the obstacle actually exists. In addition, when generating a virtual image that guides a right or left turn of a road, it is desirable to generate a virtual image at a point where the right or left turns.

  The technique disclosed in Patent Document 1 discloses that the position of the liquid crystal display panel on which an image for generating a virtual image is displayed can be moved back and forth along the optical path, and the position for generating the virtual image is adjusted. Has been.

  Here, HUD using a liquid crystal display panel as a display means for displaying an image for generating a virtual image is described in Patent Document 1, but as another method, the display means is used as a projector for projecting an image. It is also possible to configure a screen that displays an image projected from the projector. In the HUD having such a configuration, in order to display a clear image on the screen, it is necessary to accurately focus the lens of the projector on the position of the screen.

  However, for example, as shown in FIG. 19, if the screen 101 is moved toward the projection lens 102 in order to change the distance from the occupant to the virtual image far away, the focal point of the projection lens 102 is that of the screen 101 before the movement. Since the position is adjusted, the focal point shifts with respect to the screen 101 after the movement when the position of the projection lens 102 is fixed. As a result, there has been a problem that a clear image cannot be displayed on the screen 101. Further, when the screen 101 and the projection lens 102 are moved along the optical path while maintaining the distance between the screen 101 and the projection lens 102, the screen 101 and the distance from the light source of the projector to the projection lens 102 are determined. It is necessary to provide a clearance according to the movement distance of the projection lens 102, and there is a problem that the size of the HUD device increases.

  The present invention has been made in order to solve the above-described problems, and an object of the present invention is to provide a head-up display device that generates a high-quality video image as a virtual image and realizes downsizing of the device.

  In order to achieve the above object, the head-up display device (1) according to the present invention displays an image generated based on light output from the screen (20, 21) and the light source (51) with a projection lens (16, 17) a projector (4) that projects onto a screen via a virtual image generation means (11, 12) that generates a virtual image of the video from the video projected on the screen, and generates a virtual image that is visible to the user The head-up display device. Further, the light source, the projection lens, the screen, and the virtual image generating means are arranged in this order along the optical path of the light source, and the positions of the light source and the virtual image generating means are fixed with respect to the optical path, and the screen and the projection lens are along the optical path. It is configured to be movable and further includes the following means. Specifically, the virtual image position determining means (31) for determining the position for generating the virtual image, and the position for generating the virtual image by the virtual image position determining means is changed to a position farther from the user viewing the virtual image. Includes a first moving means (31) for moving the screen in a direction away from the virtual image generating means and a direction in which the projection lens is moved away from the light source, and a position for generating a virtual image by the virtual image position determining means. The second movement for moving the screen in the direction approaching the virtual image generating means and moving the projection lens in the direction approaching the light source when the position is changed to a position closer to the user who visually recognizes the virtual image. And means (31).

According to the head-up display device according to the present invention having the above-described configuration, the projection lens and the screen are moved along the optical path, so that the distance from the user to the virtual image can be adjusted by moving the screen, while the screen is moved. Even in such a case, since the image projected from the projection lens can be focused on the screen, a high-quality image can be generated as a virtual image. Moreover, since the image projected from the projection lens is focused on the screen by moving the projection lens in the direction opposite to the moving direction of the screen, there is no need to provide a clearance in the distance from the light source to the projection lens. It becomes possible to reduce the size.
Further, when the screen is moved away from the virtual image generating means, the brightness of the image projected on the screen increases due to the fact that the distance from the projection lens or the light source to the screen is reduced. On the contrary, when the screen is moved in the direction approaching the virtual image generating means, the brightness of the image projected on the screen decreases due to the distance from the projection lens or the light source to the screen being increased. As a result, even if the distance from the user to the virtual image is increased, the virtual image can be brightened, and thus visibility to the virtual image can be improved. On the other hand, when the distance from the user to the virtual image is close, it is possible to prevent the user's field of view from being blocked by the virtual image by suppressing the brightness of the virtual image.
Also, when the screen is moved away from the virtual image generating means, the image displayed on the screen even when the same image is projected from the projector due to the short distance from the projection lens to the screen The size of becomes smaller. As a result, even if the size of the image projected from the projector is not changed, if the distance from the user to the virtual image increases, the size of the virtual image can be reduced accordingly. An appropriately sized virtual image can be generated.

It is the figure which showed the installation aspect to the vehicle of HUD which concerns on this embodiment. It is the figure which showed the internal structure of HUD which concerns on this embodiment. It is the figure which showed the 1st projection lens and 2nd projection lens with which a projector is provided. It is the figure which showed the movement aspect of the 2nd projection lens. It is the figure which each showed the 1st screen and the 2nd screen. It is the figure which showed the projection aspect of the image | video of the projector with respect to the 1st screen and the 2nd screen. It is the figure which showed the movement aspect to the front-back direction with respect to the optical path of a 2nd screen. It is the figure which each showed the virtual image produced | generated by the image | video projected on the 1st screen and the 2nd screen. It is the figure which showed the movement aspect to the crossing direction with respect to the optical path of a 1st screen and a 2nd screen. It is the figure which showed the projection aspect of the image | video of a projector at the time of moving a 1st screen and a 2nd screen to an up-down direction. It is the block diagram which showed the structure of HUD which concerns on this embodiment. It is a flowchart of the table production | generation process program which concerns on this embodiment. It is the figure which showed an example of the position setting table. It is a flowchart of the virtual image generation processing program which concerns on this embodiment. It is the figure which showed an example of the virtual image visually recognizable from the passenger | crew of a vehicle. It is a flowchart of the sub process program of a 1st screen movement process. It is a flowchart of the sub process program of a 2nd screen movement process. It is the figure which showed the positional relationship of the 2nd screen and 2nd projection lens at the time of moving a 2nd screen. It is a figure explaining the problem of the prior art.

  DESCRIPTION OF EMBODIMENTS Hereinafter, an embodiment embodying a head-up display device according to the present invention will be described in detail with reference to the drawings.

  First, the configuration of a head-up display device (hereinafter referred to as HUD) 1 according to the present embodiment will be described with reference to FIG. FIG. 1 is a diagram showing an installation mode of the HUD 1 according to the present embodiment on the vehicle 2.

  As shown in FIG. 1, the HUD 1 is installed inside the dashboard 3 of the vehicle 2, and includes a projector 4 and a screen 5 on which an image from the projector 4 is projected. Then, the image projected on the screen 5 is reflected on the front window 6 in front of the driver's seat through the mirror and Fresnel lens provided in the HUD 1 as will be described later, and is made visible to the passenger 7 of the vehicle 2. ing. Note that the image projected on the screen 5 includes information related to the vehicle 2 and various information used for assisting the driving of the occupant 7. For example, warnings for obstacles (other vehicles and pedestrians), guidance information set by the navigation device and guidance information based on the guidance route (such as arrows indicating the direction of turning left and right), current vehicle speed, guidance signs, map images, traffic information, There are news, weather forecast, time, screen of connected smartphone, TV program and so on.

  Further, in the HUD 1 of the present embodiment, when the occupant 7 visually recognizes an image projected on the screen 5 by reflecting the front window 6, the occupant 7 is not at the position of the front window 6 but at the front of the front window 6. An image projected on the screen 5 at a distant position is configured to be visually recognized as a virtual image 8. The virtual image 8 that can be seen by the occupant 7 is an image projected on the screen 5, but the vertical direction is reversed because the image is projected through the mirror. In addition, the size is changed by using a Fresnel lens.

  Here, regarding the position where the virtual image 8 is generated, more specifically, the distance L from the occupant 7 to the virtual image 8 (hereinafter referred to as a generation distance) L, the shape and position of the mirror and Fresnel lens provided in the HUD 1, and the screen 5 with respect to the optical path It is possible to appropriately set the position depending on the position. In particular, in the present embodiment, the position of the screen 5 is configured to be movable in the front-rear direction along the optical path as will be described later. As a result, the generation distance L can be changed as appropriate. For example, the generation distance L can be changed between 2.5 m and 20 m.

  Next, a more specific configuration of the HUD 1 will be described with reference to FIG. FIG. 2 is a diagram showing an internal configuration of the HUD 1 according to the present embodiment.

  As shown in FIG. 2, the HUD 1 basically includes a projector 4, a screen 5, a reflection mirror 10, a mirror 11, a Fresnel lens 12, a control circuit unit 13, and a CAN interface 14.

  Here, the projector 4 is a video projection device using an LED light source as a light source, and is a DLP projector, for example. As the projector 4, a liquid crystal projector or an LCOS projector may be used. The projector 4 includes a projection lens 15 for projecting an image. In this embodiment, the projection lens 15 is composed of two projection lenses, a first projection lens 16 and a second projection lens 17, which are different from each other. Configure to project video. Here, FIG. 3 is a diagram showing the first projection lens 16 and the second projection lens 17 provided in the projector 4.

  As shown in FIG. 3, the first projection lens 16 and the second projection lens 17 have a divided shape obtained by dividing one circular lens in the vertical direction. Further, the second projection lens 17 below is configured to be movable in the front-rear direction along the optical path. On the other hand, the position of the first projection lens 16 is fixed. Specifically, by driving the lens drive motor 18 on the back side of the second projection lens 17, it is possible to move the second projection lens 17 in the front-rear direction along the optical path as shown in FIG. Become. In particular, in this embodiment, when the screen 5 is moved in the front-rear direction along the optical path as will be described later, the focal point of the image projected from the second projection lens 17 is made to coincide with the position of the screen 5 after the movement. In addition, the second projection lens 17 is also moved to follow.

  The lens drive motor 18 is a stepping motor. The HUD 1 can control the lens driving motor 18 based on the pulse signal transmitted from the control circuit unit 13 and appropriately position the second projection lens 17 with respect to the set position.

  The screen 5 is a projection medium onto which an image projected from the projector 4 is projected. For example, a Fresnel screen or a diffusion screen is used. In the present embodiment, the screen 5 includes two screens, a first screen 20 and a second screen 21. Here, FIG. 5 is a view showing the first screen 20 and the second screen 21.

  As shown in FIG. 5, the first screen 20 has a projection area 22 on which an image is projected upward, and the image projected from the first projection lens 16 of the projector 4 is displayed as shown in FIG. 6. Is done. On the other hand, the 2nd screen 21 has the to-be-projected area 23 in which an image | video is projected below, and the image | video projected from the 2nd projection lens 17 of the projector 4 is displayed as shown in FIG. The first screen 20 and the second screen 21 are arranged at predetermined intervals in the front-rear direction along the optical path so that the projection areas 22 and 23 do not overlap as shown in FIGS. 2 and 6. Therefore, in the present embodiment, the virtual image 8 includes a virtual image of a video projected on the first screen 20 (hereinafter referred to as a first virtual image 8A) and a virtual image of a video projected on the second screen 21 (hereinafter referred to as a second virtual image 8B). It will be composed of.

  The second screen 21 is configured to be movable in the front-rear direction along the optical path. On the other hand, the position of the first screen 20 is fixed with respect to the front-rear direction. Specifically, the distance between the first screen 20 and the second screen 21 is changed as shown in FIG. 7 by driving the screen front / rear drive motor 24 on the back side of the second screen 21. The two screens 21 can be moved in the front-rear direction along the optical path. As a result, the position where the second virtual image 8B, which is the virtual image of the image projected on the second screen 21, is generated (specifically, the generation distance L2 that is the distance from the occupant 7 to the second virtual image 8B) is changed. Is possible. The generation distance L2 depends on the distance from the mirror 11 to the second screen 21. That is, the generation distance L <b> 2 is changed in length depending on the distance from the mirror 11 to the second screen 21. For example, the generation distance L2 increases as the distance from the mirror 11 to the second screen 21 increases, and the generation distance L2 decreases as the distance from the mirror 11 to the second screen 21 decreases.

  For example, when the second screen 21 is moved to the projector 4 side (the side where the distance to the mirror 11 is increased), the generation distance L2 is increased (that is, the second virtual image 8B is viewed farther from the passenger 7). It becomes like). On the other hand, when the second screen 21 is moved to the side opposite to the projector 4 (the side where the distance to the mirror 11 is shortened), the generation distance L2 is shortened (that is, the second virtual image 8B is visible closer to the occupant 7). Will come to be). Since the position of the first screen 20 is fixed in the front-rear direction, the position (specifically, from the occupant 7 to the first virtual image 8A, which is a virtual image of the image projected on the first screen 20). The generation distance L1) that is the distance to one virtual image 8A is fixed. Therefore, by changing the generation distance L2, the distance (| L2-L1 |) from the first virtual image 8A to the second virtual image 8B is changed.

  Therefore, if the first screen 20 and the second screen 21 are at the same distance from the mirror 11 along the optical path, the first virtual image 8A and the second virtual image 8B are generated at the same position in front of the vehicle 2. However, when the first screen 20 and the second screen 21 are at different distances from the mirror 11 along the optical path, the first virtual image 8A and the second virtual image 8B are at different positions as shown in FIG. Will be generated. Further, as shown in FIGS. 5 and 6, each screen is arranged so that the projection area 22 of the first screen 20 is positioned above the projection area 23 of the second screen 21, but the mirror 11. Thus, the image is inverted upside down, so that the second virtual image 8B is generated above the first virtual image 8A with reference to the direction intersecting the optical path.

  In the present embodiment, the first screen 20 and the second screen 21 are configured to be integrally movable in a direction crossing the optical path. Specifically, by driving a screen vertical drive motor 25 on the side surface of the first screen 20, the first screen 20 and the second screen 21 are integrally moved in a direction crossing the optical path as shown in FIG. It becomes possible. As a result, as shown in FIG. 10, the first projection mode in which the image from the projector 4 is projected on the first screen 20 and the second screen 21, and the image from the projector 4 is projected only on the first screen 20. It is possible to switch the projection mode of the image on the screen 5 between the second projection mode to be performed.

  When the projection mode is the first projection mode, the HUD 1 basically has different types of video images (for example, the first projection lens 16 presents the current vehicle state) between the first projection lens 16 and the second projection lens 17. The vehicle speed image and the second projection lens 17 project guidance information and warning information image) on each screen. On the other hand, when the projection mode is the second projection mode, one video (for example, the first projection lens 16) that is basically a combination of the images projected by the first projection lens 16 and the second projection lens 17. Then, the image on the lower half of the television screen is projected on the first screen 20 and the image on the upper half of the television screen is projected on the second projection lens 17. As a result, in the second projection mode, it is possible to generate a larger-size image without a dividing line as a virtual image. Even in the second projection mode, the first projection lens 16 and the second projection lens 17 may be configured to project different types of images.

  Each of the screen front / rear drive motor 24 and the screen vertical drive motor 25 is a stepping motor. Then, the HUD 1 can control the screen front / rear drive motor 24 based on the pulse signal transmitted from the control circuit unit 13 and appropriately position the front / rear position of the second screen 21 with respect to the set position. The HUD 1 controls the screen vertical drive motor 25 based on the pulse signal transmitted from the control circuit unit 13 and appropriately positions the vertical positions of the first screen 20 and the second screen 21 with respect to the set position. Is possible.

  On the other hand, the reflecting mirror 10 is a reflecting plate that reflects an image projected from the projector 4 to change the optical path and projects it onto the screen 5 as shown in FIG.

  Further, the mirror 11 is a projection unit that reflects the image light from the screen 5 and projects a virtual image 8 (see FIG. 1) in front of the occupant 7 through the front window 6 as shown in FIG. 2. As the mirror 11, a spherical concave mirror, an aspheric concave mirror, or a free-form curved mirror for correcting distortion of a projected image is used.

  The Fresnel lens 12 is a magnifying glass for generating a virtual image 8 by enlarging the image projected on the screen 5 as shown in FIG. And in HUD1 which concerns on this embodiment, the image | video projected on the screen 5 is further reflected on the front window 6 via the mirror 11 and the Fresnel lens 12, and is made to be visually recognized by the passenger | crew 7, so that the front of the front window 6 is visible. The image projected on the screen 5 at a distant position is enlarged and is visually recognized by the occupant as a virtual image 8 (see FIG. 1).

  The control circuit unit 13 is an electronic control unit that controls the entire HUD 1. Here, FIG. 11 is a block diagram showing the configuration of the HUD 1 according to the present embodiment.

  As shown in FIG. 11, the control circuit unit 13 includes a CPU 31 as an arithmetic device and a control device, a RAM 32 used as a working memory when the CPU 31 performs various arithmetic processes, a control program, and a table generation described later. An internal storage device such as a ROM 33 storing a processing program (see FIG. 12), a virtual image generation processing program (see FIG. 14) and the like, a program read from the ROM 33, and a flash memory 34 for storing a position setting table described later is provided. . The control circuit unit 13 is connected to the projector 4, the lens drive motor 18, the screen front / rear drive motor 24, and the screen vertical drive motor 25, respectively, and performs drive control of the projector 4 and various motors.

  The CAN (controller area network) interface 14 is an interface for inputting / outputting data to / from CAN which is an in-vehicle network standard for performing multiplex communication between various on-vehicle devices installed in a vehicle and control devices for vehicle equipment. It is. The HUD 1 is connected to a control device (for example, the navigation device 48, the AV device 49, etc.) of various vehicle-mounted devices and vehicle equipment via the CAN so as to be able to communicate with each other. Accordingly, the HUD 1 is configured to be able to project output screens of the navigation device 48, the AV device 49, and the like.

  Next, a table generation processing program executed by the CPU 31 in the HUD 1 having the above configuration will be described with reference to FIG. FIG. 12 is a flowchart of the table generation processing program according to this embodiment. Here, the table generation processing program is a program that is executed at the time of initial setting of the HUD 1 and creates a position setting table used when the second screen 21 and the second projection lens 17 are moved. Note that the programs shown in the flowcharts of FIGS. 12 and 14 below are stored in the RAM 32 and ROM 33 provided in the HUD 1 and executed by the CPU 31.

  First, in step (hereinafter abbreviated as S) 1 in the table generation processing program, the CPU 31 uses a coefficient D (n) indicating a generation distance L2 that is a distance from the occupant 7 to the second virtual image 8B as an initial value. Set to 2.5 [m].

  Next, in S2, the CPU 31 sets the movement amount Ds (n) of the second screen 21 for displacing the generation distance L2 from the current value of D (n) to D (n) +0.1 [m]. It is calculated from the design value etc. of HUD1. The moving direction is a direction away from the mirror 11 along the optical path of the light source (a direction approaching the light source).

Subsequently, in S3, the CPU 31 moves the movement time Ts (necessary for moving the second screen 21 for displacing the generation distance L2 from the current value of D (n) to D (n) +0.1 [m]. n) is calculated from the design value etc. of HUD1. Specifically, when the second screen 21 is moved, the calculation is performed assuming that the second screen 21 is moved at the maximum moving speed. That is, when the maximum moving speed of the second screen 21 is Vs, it is calculated by the following equation (1).
Ts (n) = Ds (n) / Vs (1)

  Thereafter, in S4, the CPU 31 moves the focus of the image projected from the second projection lens 17 when the second screen 21 moves Ds (n) in the direction away from the mirror 11 (direction approaching the light source). The amount of movement Dl (n) of the second projection lens 17 necessary to match the position of the two screens 21 is calculated from the design value of the HUD 1 and the like. The moving direction is a direction opposite to the second screen 21 along the optical path of the light source, that is, a direction approaching the mirror 11 (a direction away from the light source).

Next, in S5, the CPU 31 calculates a moving speed Vl (n) for moving the second projection lens 17 from the design value of the HUD 1 or the like. Specifically, the movement of the second projection lens 17 is interlocked with the movement of the second screen 21, that is, the movement is completed simultaneously when the movement of the second projection lens 17 is started simultaneously with the second screen 21. The moving speed Vl (n) is calculated. Specifically, it is calculated by the following equation (2).
Vl (n) = Dl (n) / Ts (n) (2)

  Thereafter, in S6, the CPU 31 stores Ds (n), Ts (n), Dl (n), and Vl (n) calculated in S2 to S5 in the memory in correspondence with the current value of D (n). Store.

  Thereafter, in S7, n is counted as “+1”. Furthermore, 0.1 [m] is added to the current value of D (n).

  Next, in S8, the CPU 31 determines whether or not the current count value n is 184 or more, that is, the value of D (n) is 20.0 [m] or more with 2.5 [m] as an initial value. It is determined whether the processes of S2 to S7 have been executed every 0.1 m.

  When it is determined that the current count value n is 184 or more (S8: YES), the table generation processing program is terminated. On the other hand, when it is determined that the current count value n is less than 184 (S8: NO), the process after S2 is performed on the new value of D (n) added by 0.1 [m]. To continue.

  As a result of executing the table generation processing program, a position setting table is created based on the calculation result. As shown in FIG. 13, the position setting table includes the amount of movement of the second screen 21 when the generation distance L2 is added or subtracted by 0.1 [m] for each generation distance L2, and the second screen 21. The movement time, the movement amount of the second projection lens 17, and the movement speed of the second projection lens are stored. The moving direction of the second screen 21 is a direction away from the mirror 11 along the optical path of the light source (a direction approaching the light source) when the generation distance L2 is added by 0.1 [m], and the second projection The moving direction of the lens 17 is the opposite direction. On the other hand, when the generation distance L2 is subtracted by 0.1 [m], the moving direction of the second screen 21 is a direction approaching the mirror 11 along the optical path of the light source (a direction away from the light source), and the second projection. The moving direction of the lens 17 is the opposite direction.

  The created position setting table is stored in the flash memory 34 or the like, and is used when the second projection lens 17 and the second screen 21 are moved in a virtual image generation processing program (FIG. 14) described later. Further, the table generation processing program may be executed when the HUD 1 is first activated, or may be configured to be executed in advance on the factory side before product shipment.

  Next, a virtual image generation processing program executed by the CPU 31 in the HUD 1 will be described with reference to FIG. FIG. 14 is a flowchart of the virtual image generation processing program according to the present embodiment. Here, the virtual image generation processing program is executed after the ACC of the vehicle is turned on, and a virtual image 8 that warns the other vehicle when another vehicle traveling in another lane in front of the traveling direction of the own vehicle interrupts. Is a program that generates In the following description, it is assumed that the image projection mode on the screen 5 is always in the first projection mode (FIG. 10).

  First, in S <b> 11 in the virtual image generation processing program, the CPU 31 determines whether or not another vehicle traveling in another lane in front of the forward walking of the host vehicle has interrupted. Specifically, the distance sensor is always detected by a distance measuring sensor, and it is determined that the other vehicle has interrupted when the distance changes shorter by a predetermined amount or more at a time. Further, when the direction indicator information of the other vehicle traveling in the lane adjacent to the lane in which the host vehicle travels is acquired and it is detected that the direction indicator on the lane side in which the host vehicle travels is detected, It may be determined that an interrupt has been performed.

  And when it determines with the other vehicle which drive | works another lane ahead of the advancing walk of the own vehicle having interrupted (S11: YES), it transfers to S12. On the other hand, when it is determined that there is no interrupted vehicle (S111: NO), the virtual image generation processing program is terminated.

  In S12, the CPU 31 acquires the distance R from the own vehicle to the other vehicle that interrupted (hereinafter referred to as the interrupting vehicle) based on the detection result of the distance measuring sensor or the like. A configuration may be adopted in which the distance R is acquired using a captured image captured by the front camera instead of the distance measuring sensor.

  In S13, the CPU 31 determines whether or not the distance R acquired in S12 is 20 m or less. Note that the distance serving as the determination criterion in S13 is determined by the HUD1 standard, and specifically, is the longest generation distance L2 at which the second virtual image 8B can be generated by the HUD1. As described above, in the present embodiment, the second screen 21 is moved in the front-rear direction along the optical path to generate the second virtual image 8B that is a virtual image of the image projected on the second screen 21 (specifically, Can change the generation distance L2) that is the distance from the occupant 7 to the second virtual image 8B (see FIG. 8). When the second screen 21 is moved most toward the projector 4, the generation distance L2 is the longest. And when the longest generation distance L2 which can produce | generate the 2nd virtual image 8B by HUD1 is 20 m, the criterion of said S13 will be 20 m. On the other hand, when the longest generation distance L2 that can generate the second virtual image 8B by the HUD 1 is 30 m, the determination criterion in S13 is 30 m. In the following example, it is assumed that the longest generation distance L2 that can generate the second virtual image 8B by the HUD 1 is 20 m.

  And when it determines with the distance R acquired by said S12 being 20 m or less (S13: YES), it transfers to S14. On the other hand, when it is determined that the distance R acquired in S12 is longer than 20 m (S13: NO), the process proceeds to S15.

  In S14, the CPU 31 sets the target generation distance De, which is the target value of the generation distance L2 of the second virtual image 8B, to the distance R acquired in S12. On the other hand, in S15, the CPU 31 sets the target generation distance De, which is the target value of the generation distance L2 of the second virtual image 8B, to 20 m which is the maximum distance. Thereafter, the CPU 31 controls the position of the second screen 21 so that the second virtual image 8B is generated at a position separated from the occupant 7 by the target generation distance De set in S14 or S15 as described later.

  Subsequently, in S16, the CPU 31 acquires the current generation distance L2 of the second virtual image 8B.

  Next, in S17, the CPU 31 determines whether or not the generation distance L2 of the current second virtual image 8B acquired in S6 is equal to or less than the target generation distance De set in S14 or S15, that is, the current second virtual image. It is determined whether the position where 8B is generated is closer to the occupant side than the target position.

  When it is determined that the current generation distance L2 of the second virtual image 8B is equal to or less than the target generation distance De set in S14 or S15 (S17: YES), the process proceeds to S18. On the other hand, when it is determined that the current generation distance L2 of the second virtual image 8B is larger than the target generation distance De set in S14 or S15 (S17: NO), the process proceeds to S19.

  In S18, the CPU 31 executes a first screen movement process (FIG. 16) described later. In the first screen movement process, a position separated by the target generation distance De set in S14 or S15 based on the position setting table (FIG. 13) created in the table generation processing program (FIG. 12). Is a program for moving and controlling the positions of the second screen 21 and the second projection lens 17 so that the second virtual image 8B is generated.

  Similarly, in S19, the CPU 31 executes a second screen movement process (FIG. 17) described later. In the second screen movement process, a position separated by the target generation distance De set in S14 or S15 based on the position setting table (FIG. 13) created in the table generation process program (FIG. 12). Is a program for moving and controlling the positions of the second screen 21 and the second projection lens 17 so that the second virtual image 8B is generated.

  Next, in S <b> 20, the CPU 31 transmits a signal to the projector 4 and starts projecting an image by the projector 4. Here, the video projected by the projector 4 includes information related to the vehicle 2 and various types of information used for assisting the driving of the occupant 7. For example, warnings for obstacles (other vehicles and pedestrians), guidance information set by the navigation device and guidance information based on the guidance route (such as arrows indicating the direction of turning left and right), current vehicle speed, guidance signs, map images, traffic information, There are news, weather forecast, time, screen of connected smartphone, TV program and so on.

  In particular, in this embodiment, the image projected on the first screen 20 by the first projection lens 16 is an image of the current vehicle speed of the vehicle. The image projected onto the second screen 21 by the second projection lens 17 is a warning image for the interrupting vehicle. In the present embodiment, the second screen 21 is disposed below the first screen 20 as shown in FIG. Accordingly, as a result of reflection by the mirror 11, the second virtual image 8B that is a virtual image of the image projected on the second screen 21 is generated above the first virtual image 8A that is a virtual image of the image projected on the first screen 20. Will be.

  Therefore, as shown in FIG. 15, a numerical value indicating the current vehicle speed is generated as the first virtual image 8A in the vicinity of the lower edge of the front window 6 and in front of the front window 6, and can be visually recognized by the occupant. In addition, a frame surrounding the interrupting vehicle 61 is generated as the second virtual image 8B in the vicinity of the center of the front window 6 and in front of the front window 6, and is visible to the passenger. Here, since the position of the first screen 20 is fixed, the position where the first virtual image 8A is generated (specifically, the generation distance L1 which is the distance from the occupant 7 to the first virtual image 8A) is also fixed. The position is 2.5 m ahead of the occupant 7. The generation distance L1 may be other than 2.5 m. However, if the generation distance L1 is too long, the first virtual image 8A is embedded in the road surface, and therefore it is preferably about 2 m to 4 m.

  And in the example shown in FIG. 15, although it is set as the structure which displays the image | video of the present vehicle speed as the 1st virtual image 8A, other information, for example, a guidance sign, a map image, traffic information, news, a weather forecast, time, connected It is good also as a structure which displays also the image | video of the information which does not need to displace the distance from vehicles, such as a smart phone screen and a television program. When the generation distance L1 is fixed to an appropriate distance (for example, 2.5 m), the interrupt vehicle 61 approaches the host vehicle as shown in FIG. 15 and the position where the second virtual image 8B is generated is displaced. Even so, it is possible to prevent the generation of an unnatural virtual image that is embedded in the road surface. Furthermore, the vehicle occupant can reduce the line-of-sight movement as much as possible when visually recognizing the first virtual image 8A, and can further reduce the burden during driving.

  On the other hand, as shown in FIG. 15, the position where the second virtual image 8B is generated is the position ahead of the target generation distance De set in S14 or S15 from the vehicle occupant (ie, the position of the interrupting vehicle 61). . Therefore, the occupant can reduce the movement of the line of sight as much as possible when visually recognizing the second virtual image 8B, and can further reduce the burden during driving.

  Thereafter, in S21, the CPU 31 determines whether or not the elapsed time t from the start of video projection by the projector 4 in S20 is equal to or longer than a predetermined time Y (for example, 5 seconds). The predetermined time Y can be changed as appropriate depending on the content of the projected image.

  If it is determined that the elapsed time t from the start of the projection of the video by the projector 4 is equal to or longer than the predetermined time Y (S21: YES), the projection of the video by the projector 4 is terminated (S22). Note that only the projection by the second projection lens 17 may be terminated and the projection by the first projection lens 16 may be continued.

  On the other hand, when it is determined that the elapsed time t from the start of video projection by the projector 4 is less than the predetermined time Y (S21: NO), the process proceeds to S23.

  In S23, the CPU 31 obtains again the distance R from the own vehicle to the interrupting vehicle.

  Next, in S24, the CPU 31 determines whether or not the difference between the target generation distance De set in S14 or S15 and the distance R acquired in S21 is a predetermined distance X (for example, 2 m) or more. The predetermined distance X can be changed as appropriate depending on the content of the projected image.

  If it is determined that the difference between the target generation distance De set in S14 or S15 and the distance R acquired in S23 is equal to or greater than the predetermined distance X (S24: YES), the process proceeds to S13. To do. Thereafter, the target generation distance De is newly set based on the newly acquired distance R (S14, S15), and the second screen 21 is moved. As a result, even if the distance from the own vehicle to the interrupting vehicle has changed greatly, the second virtual image 8B can be generated at the position of the interrupting vehicle after the change.

  On the other hand, when it is determined that the difference between the target generation distance De set in S14 or S15 and the distance R acquired in S23 is less than the predetermined distance X (S24: NO), the process proceeds to S21. Then, the current image is continuously projected.

  Next, the sub-process of the first screen movement process executed in S18 will be described with reference to FIG. FIG. 16 is a flowchart of a sub-processing program for the first screen movement process.

  First, in S31, the CPU 31 determines whether or not the current generation distance L2 of the second virtual image 8B is the target generation distance De set in S14 or S15.

  When it is determined that the current generation distance L2 of the second virtual image 8B is the target generation distance De set in S14 or S15 (S31: YES), the second screen 21 and the second projection lens are used. 17 movement control is complete | finished and it transfers to S20. On the other hand, when it is determined that the current generation distance L2 of the second virtual image 8B is not the target generation distance De set in S14 or S15 (S31: NO), the process proceeds to S32.

  In S32, the CPU 31 adds 0.1 m to the current generation distance L2 based on the position setting table (FIG. 13) (that is, the position where the second virtual image 8B is generated is 0.1 m from the occupant than the current position). The amount of movement and the direction of movement of the second screen 21 are determined. The moving direction is a direction away from the mirror 11 along the optical path of the light source (a direction approaching the light source). Further, the moving speed of the second screen 21 is the maximum moving speed of the second screen 21.

  Next, in S33, the CPU 31 adds 0.1 m to the current generation distance L2 based on the position setting table (FIG. 13) (that is, the position where the second virtual image 8B is generated from the occupant rather than the current position). The moving amount, moving direction, and moving speed of the second projection lens 17 are determined. The moving direction is a direction approaching the mirror 11 along the optical path of the light source (a direction away from the light source).

  Next, in S34, the CPU 31 determines a drive amount (number of pulses) of the screen front-rear drive motor 24 necessary for moving the second screen 21 by the amount of movement determined in S32. Similarly, the driving amount (number of pulses) of the lens driving motor 18 necessary for moving the second projection lens 17 by the moving amount determined in S33 is determined.

  Subsequently, in S <b> 35, the CPU 31 transmits a signal to the projector 4 and starts correcting the video output by the projector 4. Specifically, in accordance with the change of the position of the second screen 21, processing for adjusting the distortion and size of the image projected from the second projection lens 17 to the second screen 21 is performed. Thereby, it is possible to generate an appropriate virtual image without distortion or the like even while the screen is moving.

  Next, in S36, the CPU 31 transmits to the screen front / rear drive motor 24 a pulse signal for driving the screen front / rear drive motor 24 by the drive amount determined in S34. Similarly, a pulse signal for driving the lens driving motor 18 by the driving amount determined in S34 is transmitted to the lens driving motor 18. The lens drive motor 18 is also transmitted with a signal for instructing a moving speed for moving the second projection lens 17. The screen front / rear drive motor 24 and the lens drive motor 18 that have received the pulse signal drive based on the received pulse signal. As a result, the second screen 21 moves by the same movement amount determined in the movement direction determined in S32, and the second projection lens 17 moves in the same movement direction and movement determined in S33. Move at speed.

  Subsequently, in S37, the CPU 31 determines whether or not the movement of the second screen 21 and the second projection lens 17 is completed. Specifically, the movement of the second screen 21 and the second projection lens 17 is received when a signal indicating that the drive is completed is received from the screen front / rear drive motor 24 or the lens drive motor 18 that transmitted the pulse signal in S36. Is determined to be complete.

  And when it determines with the movement of the 2nd screen 21 and the 2nd projection lens 17 having been completed (S37: YES), it transfers to S38. On the other hand, when it is determined that the movement of the second screen 21 and the second projection lens 17 is not completed (S37: NO), it waits until the movement is completed.

  In S <b> 38, the CPU 31 transmits a signal to the projector 4, and starts projecting an image on which correction corresponding to the position of the second screen 21 after the movement is performed by the projector 4. Specifically, an image whose distortion and size are corrected according to the position of the second screen 21 after movement is output. Thereafter, the process proceeds to S31, and it is determined whether or not the generation distance L2 of the second virtual image 8B after the movement of the second screen 21 has reached the target generation distance De set in S14 or S15.

  Next, the sub-process of the second screen movement process executed in S19 will be described with reference to FIG. FIG. 17 is a flowchart of a sub-processing program for the second screen movement process.

  First, in S41, the CPU 31 determines whether or not the current generation distance L2 of the second virtual image 8B is the target generation distance De set in S14 or S15.

  When it is determined that the current generation distance L2 of the second virtual image 8B is the target generation distance De set in S14 or S15 (S41: YES), the second screen 21 and the second projection lens are used. 17 movement control is complete | finished and it transfers to S20. On the other hand, when it is determined that the current generation distance L2 of the second virtual image 8B is not the target generation distance De set in S14 or S15 (S41: NO), the process proceeds to S42.

  In S42, the CPU 31 subtracts 0.1 m from the current generation distance L2 based on the position setting table (FIG. 13) (i.e., sets the position where the second virtual image 8B is generated to the occupant side relative to the current position). The moving amount and moving direction of the second screen 21 for moving 1 m) are determined. The moving direction is a direction approaching the mirror 11 along the optical path of the light source (a direction away from the light source). Further, the moving speed of the second screen 21 is the maximum moving speed of the second screen 21.

  Next, in S43, the CPU 31 subtracts 0.1 m from the current generation distance L2 based on the position setting table (FIG. 13) (i.e., the position where the second virtual image 8B is generated is occupant side from the current position). The moving amount, moving direction, and moving speed of the second projection lens 17 are determined. The moving direction is a direction away from the mirror 11 along the optical path of the light source (a direction approaching the light source).

  Next, in S44, the CPU 31 determines the drive amount (number of pulses) of the screen front / rear drive motor 24 necessary to move the second screen 21 by the amount of movement determined in S42. Similarly, the driving amount (number of pulses) of the lens driving motor 18 necessary for moving the second projection lens 17 by the moving amount determined in S43 is determined. Since the subsequent processing of S44 to S48 is the same as the processing of S34 to S38 of the first screen movement processing (FIG. 16) already described, description thereof will be omitted.

  Here, the positions of the second screen 21 and the second projection lens 17 are configured to be movable along the optical path 52 of the light source 51 of the projector 4 as shown in FIG. Since the generation distance L2 depends on the distance from the mirror 11 to the second screen 21, the position of the second screen 21 in the first screen movement process (FIG. 16) and the second screen movement process (FIG. 17) described above. Is moved so that the distance from the mirror 11 to the second screen 21 is a distance corresponding to the target generation distance De set in S14 or S15.

  On the other hand, the position of the second projection lens 17 is determined as a position where the image projected from the second projection lens 17 is focused on the second screen 21. In other words, if the second screen 21 moves along the optical path in a direction away from the mirror 11 (that is, a direction approaching the second projection lens 17) in order to increase the generation distance L2, the second projection lens 17 follows the optical path. Therefore, it moves in a direction approaching the second screen 21 which is the opposite direction. On the other hand, if the second screen 21 moves along the optical path in a direction approaching the mirror 11 (that is, a direction away from the second projection lens 17) in order to shorten the generation distance L2, the second projection lens 17 follows the optical path. Therefore, it moves in the direction away from the second screen 21 which is the opposite direction. In addition, as described above, the second screen 21 repeats until the generation distance L2 reaches the target generation distance De set in S14 or S15, with the movement amount by which the generation distance L2 is displaced by 0.1 m as the first unit amount. Move (S32 to S37, S42 to S47). Further, each time the second screen 21 moves by the first unit amount, the second projection lens 17 moves by the second unit amount so that the image is focused on the second screen 21 after the movement. In addition, the time for the second screen 21 to move by the first unit amount is the same as the time for the second projection lens 17 to move by the second unit amount, and the movement start timing is also linked.

  As a result, even if the second screen 21 is moved toward the second projection lens 17 in order to change the generation distance L2, the second screen 21 is mirrored to change the generation distance L2. Even when moved to the 11th side, it is possible to maintain a state where the focus of the image projected from the second projection lens 17 is always on the second screen 21. As a result, a clear image can be projected even during and after the movement of the second screen 21.

  Further, if the second screen 21 is moved toward the second projection lens 17 in order to change the generation distance L2 longer, the distance from the second projection lens 17 or the light source 51 to the second screen 21 becomes a factor. As a result, the brightness of the image projected on the second screen 21 increases. Conversely, if the second screen 21 is moved away from the second projection lens 17 in order to shorten the generation distance L2, the distance from the second projection lens 17 or the light source 51 to the second screen 21 is increased. As a factor, the brightness of the image projected on the second screen 21 decreases. As a result, even when the distance from the vehicle occupant to the second virtual image 8B is increased, the second virtual image 8B can be brightened, so that the visibility to the second virtual image 8B can be improved. . On the other hand, when the distance from the vehicle occupant to the second virtual image 8B is short, it is possible to prevent the occupant's field of view from being blocked by the second virtual image 8B by suppressing the brightness of the second virtual image 8B. It becomes possible.

  In addition, when the second screen 21 is moved to the second projection lens 17 side in order to change the generation distance L2 to be longer, the same is caused because the distance from the second projection lens 17 to the second screen 21 is reduced. Even when the video is projected from the projector 4, the size of the video projected on the second screen 21 is reduced. As a result, even if the size of the image projected from the projector 4 is not changed, if the distance from the vehicle occupant to the second virtual image 8B increases, the size of the second virtual image 8B can be reduced accordingly. It becomes possible to generate a virtual image of an appropriate size according to the distance from the occupant to the second virtual image 8B.

As described above in detail, according to the HUD 1 according to the present embodiment, images are projected from the projector 4 using the LED light source via the first projection lens 16 and the second projection lens 17, respectively. The image projected on the screen 21 and reflected to the front window 6 of the vehicle 2 by the image projected on the first screen 20 and the second screen 21 to be visually recognized by the vehicle occupant 7 allows the image of the image viewed by the vehicle occupant 7 to be viewed. Generate a virtual image. The second projection lens 17 and the second screen 21 are independently movable along the optical path, and the second screen 21 is moved to adjust the generation distance L2 from the occupant to the virtual image. Since the second projection lens 17 is moved in accordance with the movement of the second screen 21 so that the image projected from the projection lens 17 is focused on the second screen 21, the occupant 7 is moved by moving the second screen 21. While the generation distance L2 from the second virtual image 8B to the second virtual image 8B can be adjusted, the image projected from the second projection lens 17 can be focused on the second screen 21 even when the second screen 21 is moved. Therefore, it is possible to generate a high-quality image as a virtual image. In addition, by moving the second projection lens 17 in the direction opposite to the moving direction of the second screen 21, the image projected from the second projection lens 17 is focused on the second screen 21. It is not necessary to provide a clearance in the distance to the two projection lenses 17, and the apparatus can be miniaturized.
Further, when the second screen 21 is moved away from the mirror 11, the projection from the second projection lens 17 or the light source 51 to the second screen 21 is caused on the second screen 21 due to the short distance. The brightness of the recorded image increases. Conversely, when the second screen 21 is moved in the direction approaching the mirror 11, the distance from the second projection lens 17 or the light source 51 to the second screen 21 becomes a factor on the second screen 21. The brightness of the projected image decreases. As a result, even when the distance from the vehicle occupant to the second virtual image 8B is increased, the second virtual image 8B can be brightened, so that the visibility to the second virtual image 8B can be improved. . On the other hand, when the distance from the vehicle occupant to the second virtual image 8B is short, it is possible to prevent the occupant's field of view from being blocked by the second virtual image 8B by suppressing the brightness of the second virtual image 8B. It becomes possible.
In addition, when the second screen 21 is moved away from the mirror 11, the same image is projected from the projector 4 because the distance from the second projection lens 17 to the second screen 21 is reduced. Even if it exists, the size of the image projected on the second screen 21 is reduced. As a result, even if the size of the image projected from the projector 4 is not changed, if the distance from the vehicle occupant to the second virtual image 8B increases, the size of the second virtual image 8B can be reduced accordingly. It becomes possible to generate a virtual image of an appropriate size according to the distance from the vehicle occupant to the second virtual image 8B.

Note that the present invention is not limited to the above-described embodiment, and various improvements and modifications can be made without departing from the scope of the present invention.
For example, in the present embodiment, the virtual image is generated in front of the front window 6 of the vehicle 2 by the HUD 1, but the virtual image may be generated in front of a window other than the front window 6. In addition, the object to be reflected by the HUD 1 may be a visor (combiner) installed around the front window 6 instead of the front window 6 itself.

  In the present embodiment, the HUD 1 is installed on the vehicle 2. However, the HUD 1 may be installed on a moving body other than the vehicle 2. For example, it can be installed on a ship or an aircraft. Moreover, you may install in the ride type attraction installed in an amusement facility. In that case, a virtual image can be generated around the ride so that the rider can visually recognize the virtual image.

  Further, in the present embodiment, the first virtual image 8A does not need to change the generation distance of the current vehicle speed, guidance signs, map images, traffic information, news, weather forecast, time, connected smartphone screen, TV program, and the like. The information virtual image is displayed, but the first virtual image 8A is similar to the second virtual image 8B, and the image regarding an object such as an obstacle or an intersection whose distance from the vehicle is displaced (that is, the generation distance needs to be displaced). (Information) may be displayed.

  In the present embodiment, only the second screen 21 is configured to be movable in the front-rear direction along the optical path. However, the first screen 20 may be configured to be movable. Similarly, the first projection lens 16 may be configured to be movable. In that case, the generation distance L1 of the first virtual image 8A can be changed.

  In this embodiment, the screen is composed of two screens, a first screen 20 and a second screen 21, and the lens of the projector 4 is composed of two lenses, a first projection lens 16 and a second projection lens 17. However, the number of screens and lenses may be only one pair or three or more pairs. Further, as the light source of the projector 4, a lamp or a laser may be used in addition to the LED.

  Moreover, although the embodiment which actualized the head-up display device according to the present invention has been described above, the head-up display device can also have the following configuration, and in that case, the following effects can be obtained.

For example, the first configuration is as follows.
The first moving unit and the second moving unit are characterized in that the image projected from the projection lens is focused on the screen by moving the projection lens and the screen along the optical path.
According to the head-up display device having the above-described configuration, the distance from the user to the virtual image can be adjusted by moving the screen, while the image projected from the projection lens is displayed on the screen even when the screen is moved. Since focusing can be performed, it is possible to generate a high-quality image as a virtual image.

The second configuration is as follows.
Based on the position determined by the virtual image position determining means, the screen movement determining means for determining the moving direction and moving amount for moving the screen, and based on the moving direction and moving amount of the screen determined by the screen moving determining means, Lens movement determining means for determining a moving direction and a moving amount for moving the projection lens, and the first moving means and the second moving means move the screen according to the moving direction and the moving amount determined by the screen moving determining means. The projection lens is moved according to the moving direction and the moving amount determined by the lens movement determining means.
According to the head-up display device having the above configuration, after determining the position for generating the virtual image, the moving direction and the moving amount of the screen are determined based on the determined position of the virtual image, so the distance from the user is displaced. When displaying an image related to an object such as an obstacle or an intersection as a virtual image, it is possible to generate a virtual image at an appropriate position according to the distance from the user to the object. Furthermore, since the movement direction and movement amount of the projection lens are determined based on the determined movement direction and movement amount of the screen, projection is performed while generating a virtual image at an appropriate position according to the distance from the user to the object. It is also possible to focus the image projected from the lens on the screen.

The third configuration is as follows.
The first moving means and the second moving means move the moving amount determined by the screen moving determining means in the first operation of moving the screen by a predetermined first unit amount in the moving direction determined by the screen moving determining means. Until the movement amount determined by the lens movement determination means is moved, and the second operation of moving the projection lens in the movement direction determined by the lens movement determination means is repeated until the movement amount determined by the lens movement determination means is moved. Each time the first operation is performed on the screen, the second operation is performed on the projection lens so that the image projected from the projection lens is focused on the screen after moving the first unit amount. And
According to the head-up display device having the above configuration, even when the screen is moved to the projection lens side or the opposite side in order to change the position where the virtual image is generated, the image projected from the projection lens The focus can always be kept on the screen. As a result, a clear image can be projected during and after the movement of the screen.

The fourth configuration is as follows.
The first operation and the second operation are started at the same timing, and the value obtained by dividing the second unit amount by the time required for the screen to move the first unit amount is moved by the lens moving means. It is characterized by speed.
According to the head-up display device having the above configuration, since the movement of the screen and the projection lens can be linked, the screen is projected from the projection lens before, during and after the movement of the first unit amount. The image can be kept focused on the screen at all times.

The fifth configuration is as follows.
The projector is characterized in that while the screen is being moved by the first moving means and the second moving means, the image is continuously projected onto the screen while correcting the image according to the change in the position of the screen.
According to the head-up display device having the above configuration, it is possible to generate an appropriate virtual image without distortion or the like even while the screen is moving.

DESCRIPTION OF SYMBOLS 1 Head up display apparatus 2 Vehicle 3 Dashboard 4 Projector 5 Screen 6 Front window 7 Crew 8 Virtual image 16 1st projection lens 17 2nd projection lens 18 Lens drive motor 20 1st screen 21 2nd screen 24 Screen front and rear drive motor 25 screen Vertical drive motor 31 CPU
32 RAM
33 ROM
34 Flash memory 51 Light source 52 Optical path

Claims (6)

Screen,
A projector that projects an image generated based on light output from a light source onto the screen via a projection lens;
Virtual image generating means for generating a virtual image of the video from the video projected on the screen;
Virtual image position determining means for determining a position for generating the virtual image,
Arranged in order of the projection lens, the screen, and the virtual image generating means from the light source along the optical path of the light source,
The positions of the light source and the virtual image generating means are fixed with respect to the optical path, and the screen and the projection lens are configured to be movable along the optical path,
The virtual image position determining means determines a distance from the user viewing the virtual image to the virtual image as a position for generating the virtual image,
When the position where the virtual image position determining unit generates the virtual image is changed to a position farther from the user viewing the virtual image, the screen is moved away from the virtual image generating unit. First moving means for moving the projection lens in a direction away from the light source;
When the position at which the virtual image is generated by the virtual image position determining means is changed to a position closer to the user viewing the virtual image, the screen is moved in a direction approaching the virtual image generating means. And a second moving means for moving the projection lens in a direction approaching the light source.   The first moving unit and the second moving unit focus the image projected from the projection lens on the screen by moving the projection lens and the screen along the optical path. The head-up display device according to claim 1. Screen movement determining means for determining a moving direction and a moving amount for moving the screen based on the position determined by the virtual image position determining means;
A lens movement determining means for determining a moving direction and a moving amount for moving the projection lens based on the moving direction and the moving amount of the screen determined by the screen movement determining means,
The first moving means and the second moving means move the screen according to the moving direction and moving amount determined by the screen moving determining means, and according to the moving direction and moving amount determined by the lens moving determining means. The head-up display device according to claim 1, wherein the projection lens is moved. The first moving means and the second moving means are:
The first operation of moving the screen in a predetermined first unit amount in the movement direction determined by the screen movement determination unit is repeatedly performed until the movement amount determined by the screen movement determination unit is moved,
The second operation of moving the projection lens in a movement direction determined by the lens movement determination unit by a predetermined second unit amount is repeated until the movement amount determined by the lens movement determination unit is moved,
Each time the first operation is performed on the screen, the second image is projected on the projection lens so that the image projected from the projection lens is focused on the screen after moving the first unit amount. 4. The head-up display device according to claim 3, wherein the head-up display device performs the following operations. The first operation and the second operation are started at the same timing,
5. A value obtained by dividing the second unit amount by a time required for the screen to move the first unit amount is set as a moving speed of the projection lens by the lens moving unit. The head-up display device described in 1.   While the screen is being moved by the first moving means and the second moving means, the projector continuously projects the image on the screen while correcting the image according to a change in the position of the screen. The head-up display device according to claim 1, wherein the head-up display device is a head-up display device.

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