JP6528962B2 - Head-up display - Google Patents

Description

  The present invention relates to a head-up display for displaying a virtual image.

  The head-up display displays augmented reality (AR: Augmented Reality), which adds information etc. to a real scene or highlights a specific object, by superimposing a superimposed image on the scenery in front of the host vehicle (real scene). It is possible to contribute to safe and comfortable vehicle operation by providing desired information accurately while suppressing the line-of-sight movement of the user who generates and drives the vehicle as much as possible.

  By the way, there are cases where drivers with different physiques board the vehicle on which the head-up display is mounted. The head-up display rotates the relay optical system capable of controlling the direction of the display light provided inside the head-up display because the height of the viewpoint from which the virtual image of the head-up display is viewed is different when the driver's physique is different. It is desirable that the display light be controlled to be directed to a predetermined viewpoint height by moving the light.

  When the direction of the display light is adjusted, the incident angle of the display light entering the front windshield (transmission reflection surface) of the vehicle from the head-up display changes. Since the reflectance of the display light depends on the incident angle with respect to the reflection surface (transmission reflection surface), the brightness of the virtual image to be recognized is different due to the difference in height of the viewpoint.

  For example, the head-up display disclosed in Patent Document 1 adjusts the direction of the display light by rotating the concave mirror, and the display light emitted from the head-up display according to the direction (projection position) to which the display light is directed. By adjusting the output intensity, the variation in luminance of the virtual image visually recognized due to the difference in height of the viewpoint is suppressed.

JP, 2009-132221, A

  However, in the output intensity adjustment of display light assuming a naked eye as disclosed in Patent Document 1, when the user wears polarized sunglasses, a virtual image visually recognized according to the difference in the incident angle of the display light to the transmission / reflection surface The present inventors recognized that the brightness of the LED was uneven.

  Therefore, one object of the present invention is to provide a head-up display that suppresses unintended variations in luminance according to the difference in the incident angle of the display light with respect to the transmission / reflecting surface regardless of whether the polarized sunglasses are worn or not worn It is.

The present invention adopts the following means in order to solve the problems.
The present invention adjusts the luminance of the display image displayed by the image display unit according to the incident angle of the display light to the transmission / reflecting surface, thereby making the unintended luminance dispersion of the virtual image caused by the difference in the height of the occupant's viewpoint. In the case where the polarized sunglasses are not worn, the projection position of the display light can be suppressed by switching the brightness adjustment mode in which the change rate of the brightness adjustment of the display image differs according to the incident angle of the display light to the transmission / reflection surface. The brightness adjustment of the display image can be moderated accordingly, and when wearing polarized sunglasses, the brightness adjustment of the display image is made sharper than when not wearing polarized sunglasses according to the projection position of the display light Therefore, the present invention is characterized in that it is possible to suppress unintended variations in luminance due to differences in the projection position of the display light regardless of whether the light sunglasses are worn or not worn.

  In the head-up display according to the present invention, an image display unit for displaying a display image on a display surface, and display light of the display image displayed on the display surface by the image display unit on a transmission / reflection surface arranged in front of a user The relay optical system to be directed, a first adjustment mode for adjusting the light intensity of the display light according to the size of the incident angle of the display light to the transmission / reflection surface, and the transmission / reflection surface compared to the first adjustment mode A display control unit capable of controlling the image display unit by switching at least a second adjustment mode of adjusting the change rate of the light intensity of the display light with respect to the size of the incident angle of the display light with respect to Is provided.

  It is possible to suppress unintended variations in luminance due to the difference in the incident angle of the display light with respect to the transmission / reflecting surface regardless of whether or not the polarized sunglasses are worn.

It is a figure which shows the example of a structure of the head-up display of this invention. It is a figure which shows the example of a structure of the image display part shown by FIG. It is a figure which shows the example of a structure of the control part shown by FIG. The relationship between the relative brightness of the virtual image of the head-up display shown by FIG. 1 and the incident angle of the display light which injects into a transmission reflective surface is shown. It is a flowchart which shows the example of the process which the head-up display shown by FIG. 1 performs.

  The embodiments described below are used to facilitate understanding of the present invention, and those skilled in the art should note that the present invention is not unduly limited by the embodiments described below.

  The configuration of a head-up display (hereinafter referred to as HUD) 100 of the present invention will be described with reference to FIG.

  As shown in FIG. 1, the HUD 100 is mounted on, for example, a vehicle 1 and projects display light K such as vehicle information on a part of a front windshield (an example of a transmission / reflection surface) 1 a of the vehicle 1. The front windshield 1 a reflects the display light K toward the user (for example, the driver of the vehicle 1) to generate a predetermined eye box 2. The user places the virtual image 201 in the virtual image area 200 virtually generated in the forward direction (traveling direction of the vehicle 1) via the front windshield 1a by placing the viewpoint 3 (user's eye) in the eye box 2. It can be viewed visually. Note that the virtual image 201 is viewed from the eye box 2 (the position of the viewpoint) in the forward direction (the traveling direction of the vehicle 1), for example, at a position of 5 m to 10 m apart. Although only one virtual image region 200 is shown in FIG. 1, display light emitted from the image display unit 10 based on the relay optical system 20 provided with a plurality of image display units 10 described later and / or described later A plurality of virtual image areas 200 having different distances from the eye box 2 may be generated by using a technique such as adjusting the imaging distance of K, and the virtual image 201 may be displayed on each virtual image area 200.

  In the vehicle 1 of FIG. 1, an operation unit 5 operated by a user is mounted. The operation unit 5 of FIG. 1 is configured by, for example, a plurality of push switches provided on a steering wheel (not shown) of the vehicle 1. The operation unit 5 outputs the operation information C according to the operation performed by the user to the control unit 40 (interface 43) described later. The operation unit 5 may be provided at a location other than the steering in the vehicle 1. Alternatively, the operation signal of a portable device (not shown) such as a smartphone may be wirelessly received on the side of the vehicle 1 to substitute for the operation unit 5.

  The operation information C includes, for example, information indicating whether the user wears or does not wear polarized sunglasses, and information for operating the actuator 30, which will be described later, and the HUD 100 uses the operation information C indicating the wearing state of the polarized sunglasses. The actuator 30 is driven by operation information C for switching between the first adjustment mode (mounting mode) or the second adjustment mode (non-mounting mode) to be operated or operating the actuator 30 of the HUD 100 described later to drive the relay optical system 20 Rotate and / or move the Also, the operation information C may include, for example, information on the degree of polarization of polarized sunglasses, specifically, information indicating the numerical value of the degree of polarization of polarized sunglasses, the magnitude of the degree of polarization, and the like. The HUD 100 adjusts the rate of change of the light intensity of the display light K with respect to the incident angle θ of the display light K to the front windshield 1 a based on the operation information C indicating the polarization degree of the polarized sunglasses. The operation of these HUDs 100 will be described in detail later.

  The vehicle 1 in FIG. 1 is equipped with a viewpoint position detection unit 6 that detects the position of the viewpoint 3 of the user. For example, the viewpoint position detection unit 6 of FIG. 1 is installed on a ceiling inside the vehicle 1, and an imaging unit (not shown) that images a user, and an image analysis unit that analyzes a captured image of the user captured by the imaging unit. And (not shown). The imaging unit is, for example, a monocular or compound eye visible light camera or an infrared camera, and the image analysis unit is, for example, an imaging of a user captured by the imaging unit using known image processing, pattern matching method, or the like. By image analysis of the image, at least the position (height) of the user in the vertical direction of the viewpoint 3 is detected, and viewpoint position information G related to the position of the viewpoint 3 is output to the HUD 100 (control unit 40).

  The viewpoint position information G includes, for example, information on the height of the viewpoint 3 of the user in the vertical direction, and the HUD 100 controls the actuator 30 described later based on the viewpoint position information G indicating the height of the viewpoint 3. The relay optical system 20 is moved or / and rotated. Thereby, the eye box 2 generated by the HUD 100 can be aligned with the position of the viewpoint 3 of the user. Hereinafter, moving or rotating the relay optical system 20 is also referred to simply as driving.

  The HUD 100 of FIG. 1 includes, for example, an image display unit 10, a relay optical system 20, an actuator 30, and a control unit 40. The HUD 100 is generally housed in the dashboard of the vehicle 1, but even if all or part of the image display unit 10, the relay optical system 20, the actuator 30, and the control unit 40 are disposed outside the dashboard Good. The HUD 100 (control unit 40) is connected to a bus 4 including an on-board LAN (Local Area Network) mounted on the vehicle 1, and can input part or all of vehicle information from the bus 4.

  FIG. 2 is a diagram showing an example of the configuration of the image display unit 10 shown in FIG. In order to facilitate the following description, as shown in FIG. 2, when the display surface 11 of the image display unit 10 is viewed from the front, the horizontal direction of the display surface 11 is the dx axis (the right direction is the dx axis positive direction) And the vertical direction is defined as the dy axis (the upper direction is the dy axis positive direction). The dx axis positive direction on the display surface 11 shown in FIG. 2 corresponds, for example, to the right direction toward the traveling direction of the vehicle 1 in the real space of FIG. Similarly, the dy axis positive direction on the display surface 11 shown in FIG. 2 corresponds, for example, to the upper side in the vertical direction in the real space of FIG. 1. When the display light K from the image display unit 10 is reflected by the relay optical system 20 or the like before reaching the eye box 2, the dx axis positive direction or / and the dy axis positive direction of the display surface 11 of FIG. The relationship between the horizontal direction of the real space in FIG. 1 and / or the vertical direction may be reversed.

  As shown in FIG. 2, the image display unit 10 displays the display image 12 on the display surface 11 based on the display surface 11 for displaying the display image 12 and the image data D generated by the control unit 40 described later. And a driving circuit. The image data D may include, for example, luminance information Q related to the luminance for each area in the display surface 11, and the image display unit 10 uses the information to display the display image 12 in the display surface 11 You may want to The display light K emitted from the display surface 11 of the image display unit 10 is guided to the windshield 1a by the relay optical system 20, and the virtual light 201 can be displayed by the display light K reflected to the user side by the windshield 1a. Virtual virtual image region 200 is generated. The display image 12 displayed on the display surface 11 is displayed as a virtual image 201 on the virtual image area 200. The image display unit 10 can adjust the luminance of the display image 12 on the display surface 11 based on the luminance information Q included in the image data D.

  The image display unit 10 emits non-polarized display light K. For example, a reflective display panel such as a DMD or a self-luminous display panel such as an organic EL element can be applied. The relay optical system 20 may be a reflecting optical system such as a plane mirror, a curved surface mirror, or a free curved surface mirror, or a transmissive or refractive optical system such as a curved surface lens or a free curved surface lens, or a semi-transmissive optical such as a half mirror Systems and the like are applicable. The relay optical system 20 typically has a function of enlarging the display light K generated by the image display unit 10, a function of correcting the distortion of the front windshield 1a, and allowing the virtual image 201 without distortion to be recognized. And has a function of imaging at a position separated by a predetermined distance from. Further, although one image display unit 10 and one relay optical system 20 are illustrated in FIG. 1, a plurality of each may be provided.

  The actuator 30 includes, for example, a driving unit (not shown) such as a stepping motor or a DC motor, and a driving mechanism for moving or rotating the relay optical system 20 as desired by the driving force from the driving unit. The actuator 30 drives the relay optical system 20 based on drive data T from the control unit 40 described later, thereby adjusting the projection position of the display light K on the front windshield 1 a and moving the eye box 2. Is possible. When the projection position of the display light K on the front windshield 1a is adjusted, the incident angle θ of the display light K for generating the eyebox 2 on the front windshield 1a also changes. Incidentally, in the present embodiment, the actuator 30 adjusts the projection position of the display light K with respect to the front windshield 1a by driving the relay optical system 20. However, the actuator 30 moves the housing of the HUD 100 or And the projection position of the display light K with respect to the front windshield 1a may be adjusted by rotating. In addition, the actuator 30 and / or the relay optical system 20 may not be singular but may be plural.

  FIG. 3 shows an example of a schematic configuration of the control unit 40 of FIG. As shown in FIG. 3, the control unit 40 controls the display of the image display unit 10, and includes, for example, a processing unit 41, a storage unit 42, and an interface 43. The processing unit 41 is configured by, for example, a CPU and a RAM, the storage unit 42 is configured by, for example, a ROM, and the interface 43 is configured by an input / output communication interface connected to the bus 4. For example, the interface 43 can acquire vehicle information, operation information C, viewpoint position information G, and the like via the bus 4. The storage unit 42 includes data for generating drive data T for driving the actuator 30 based on the input operation information C, data for generating image data D based on vehicle information and the like, and operation information C. Alternatively, data or the like for generating luminance information Q for adjusting the luminance of the display image 12 based on the viewpoint position information G or the drive data T can be stored. The processing unit 41 can generate the drive data T, the image data D, and the luminance information Q by reading data from the storage unit 42 and executing a predetermined operation. The processing unit 41 generates luminance information Q by performing luminance adjustment processing described later, and adjusts the luminance of the virtual image 201. The interface 43 acquires, for example, operation information C of the user from the operation unit 5 via the bus 4 and viewpoint position information G including information on the position of the viewpoint 3 of the user from the viewpoint position detection unit 6 And has functions as an operation information acquisition unit and a viewpoint position information acquisition unit described in the claims of the present invention. The control unit 40 also has a function as a display control unit that controls the image display unit 10 described in the claims of the present invention. The control unit 40 may be inside the HUD 100, and a part or all of the functions may be provided on the vehicle 1 side outside the HUD 100.

  FIG. 4 shows the case where the HUD 100 of the present invention does not execute the “brightness adjustment process”, and the brightness of the virtual image 201 when the incident angle θ of the display light K to the front windshield 1a shown in FIG. It is the figure which showed the relative luminance L of the virtual image 201 which made the reference | standard (relative luminance L 1), and has shown the result of the simulation which this inventor performed using the formula of Fresnel. As shown in FIG. 4, as the incident angle θ of the display light K to the front windshield 1 a increases, the relative brightness L of the virtual image 201 increases. Further, the rate of change of the relative brightness L of the virtual image 201 with respect to the incident angle θ when the user wears polarized sunglasses is larger than the rate of change of the relative brightness L of the virtual image 201 when the user does not wear polarized sunglasses. The reason for this will be described below.

  Assuming that the windshield 1a is a transmission / reflection surface that reflects the display light K, the reflected light of the display light K reflected by the transmission / reflection surface 1a and directed to the user is the locus and reflection of the incident light incident on the transmission / reflection surface 1a. An S-polarization component in which the electric field vector vibrates in a perpendicular direction (a direction parallel to the horizontal surface (ground)) with respect to a virtual plane including the reflected light trajectory is mainly used. Therefore, in a state where the user does not wear polarized sunglasses, the display light K mainly composed of the S-polarization component is incident on the user's eyes, so the luminance of the virtual image 201 visually recognized by the user is the transmissive reflective surface 1a. It largely depends on the light intensity of the much reflected S polarization component. On the other hand, in the polarized sunglasses, when worn by the driver of the vehicle 1, the polarization axis of the polarization direction of the electric field component of light does not transmit the polarized light (S polarized light) parallel to the horizontal plane (ground). Have. That is, since the polarized sunglasses do not transmit the light of the S-polarized component that is reflected a lot by the transmission / reflection surface 1a, the luminance of the virtual image 201 visually recognized by the user is orthogonal to the horizontal surface (ground) included in the display light K Depends on the light intensity of the P polarization component of The incident angle θ of the display light K with respect to the transmitting / reflecting surface 1a varies depending on the type of vehicle, but is generally set in the range of 50 degrees to 75 degrees, and the rate of change of reflectance according to the incident angle In the range of 50 degrees to 75 degrees, the incident angle θ is larger than the change rate of the reflectance of S-polarized light. Therefore, the rate of change of the relative brightness L of the virtual image 201 when the user wears polarized sunglasses is larger than the rate of change of the relative brightness L of the virtual image 201 when the user does not wear polarized sunglasses.

  The HUD 100 of the present invention adjusts the brightness of the display image 12 displayed by the image display unit 10, for example, with the transition of the relative brightness L of the virtual image 201 with respect to the incident angle θ as shown in FIG. Even when the incident angle θ of the display light K directed from the HUD 100 toward the user to the front windshield 1a is different, the unintended luminance difference of the virtual image 201 can be suppressed. Below, with reference to FIG. 5, the example of the flow of the "brightness adjustment process" which HUD100 of this invention performs is shown.

  FIG. 5 is a flowchart illustrating an example of the brightness adjustment process performed by the HUD 100. The brightness adjustment process of the HUD 100 is performed, for example, when the vehicle 1 is activated, or when the electronic device of the vehicle 1 is supplied with power, or when the vehicle 1 is activated or when the electronic device of the vehicle 1 is powered. It starts when time passes.

  In step S01, the control unit 40 acquires viewpoint position information G including operation information C of the user from the operation unit 5 or information on the position of the viewpoint 3 of the user from the viewpoint position detection unit 6.

  In step S02, control unit 40 determines drive data T including the drive amount of actuator 30 corresponding to operation information C or viewpoint position information G acquired in step S01, and drives actuator 30 based on this drive data T. Do. Specifically, control unit 40 reads table data stored in advance in storage unit 42, and determines drive data T corresponding to operation information C or viewpoint position information G acquired in step S01, and the determined drive data By driving the actuator 30 based on T, the relay optical system 20 is moved or rotated and the projection position of the display light K of the HUD 100 on the windshield 1 a is moved in the vertical direction. In step S02, the control unit 40 may calculate the drive data T from the operation information C or the viewpoint position information G by using a calculation formula set in advance.

  In step S03, the control unit 40 performs the first adjustment mode in which the brightness of the virtual image 201 is adjusted according to the state in which the user wears polarized sunglasses, and the virtual image 201 according to the state in which the user does not wear polarized sunglasses. The brightness adjustment is performed to switch between the second adjustment mode in which the change rate of the brightness with respect to the change of the viewpoint position information G and the drive data T is smaller than that in the first adjustment mode. Specifically, for example, the control unit 40 switches the first and second adjustment modes based on operation information for switching the mode by the user from the operation unit. Further, for example, the control unit 40 inputs the wearing determination information in which the wearing state of the polarization sunglasses is determined by the viewpoint position detecting unit 6 imaging the user and analyzing the captured image, and based on the wearing determination information, The first and second adjustment modes may be switched.

  In step S04, the control unit 40 displays the viewpoint position information G or the drive data T generated in step S02 on the display surface 11 of the image display unit 10 in accordance with the adjustment mode switched in step S03. The brightness of the display image 12 is adjusted. Specifically, for example, the control unit 40 reads from the storage unit 42 table data in which the viewpoint position information G of the adjustment mode determined in step S03 and the luminance information Q of the display image 12 are associated, and the viewpoint input in step S01. The display image 12 is displayed with luminance information Q based on the position information G. Further, the control unit 40 reads out from the storage unit 42 table data in which the drive data T in the adjustment mode determined in step S03 and the luminance information Q of the display image 12 are associated with each other, and based on the drive data T determined in step S02. The display image 12 may be displayed with the luminance information Q. By the way, step S02 and steps S03, S04 and S05 do not necessarily have to be in this order, and may be executed at the same time or in different order.

  As described above, the HUD 100 of the present invention adjusts the light intensity of the display light K output from the image display unit 10 in accordance with the incident angle θ of the display light K to the transmission / reflection surface 1a; And a second adjustment mode in which the light intensity of the display light K output from the image display unit 10 is adjusted such that the change rate of the light intensity of the display light K with respect to the projection position of the display light K is larger than that in the first adjustment mode. ,have. Therefore, the HUD 100 adjusts the brightness of the image display unit 10 according to the change of the incident angle θ of the display light K to the front windshield 1 a using the first adjustment mode in which the change rate of the display light K is small. Thus, a virtual image 201 of desired brightness can be viewed by a user who does not wear polarized sunglasses. Further, the HUD 100 adjusts the brightness of the image display unit 10 according to the change of the incident angle θ of the display light K to the front windshield 1 a using the second adjustment mode in which the change rate of the display light K is large. Thus, the virtual image 201 of desired brightness can be viewed by a user wearing polarized sunglasses.

  When the angle of view of the virtual image 201 is large and the display light K is projected in a wide range of the front windshield 1 a, the display light K directed to the user according to the displayed position in the display surface 11 of the image display unit 10 The incident angle θ with respect to the front windshield 1a is largely different, and the luminance of the virtual image 201 is largely different according to the displayed position in the virtual image area 200. Therefore, the light intensity of the display light K emitted from each area of the display surface 11 of the image display unit 10 by using the first or second adjustment mode as described above corresponds to the display light K for the front windshield 1 a. It may be adjusted stepwise or continuously depending on the incident angle θ of

  The HUD 100 of the present invention may not have the actuator 30 for driving the relay optical system 20. Even when the relay optical system 20 is not driven, the incident angle θ of the display light K directed to the user's viewpoint 3 with respect to the front windshield 1 a changes according to the change in the position of the user's viewpoint 3. In this case, the HUD 100 of the present invention may adjust the light intensity of the display light K output from the image display unit 10 according to the viewpoint position information G.

  The head-up display of the present invention can be applied to a head-up display for visually recognizing a virtual image mounted on a mobile object such as a vehicle.

  DESCRIPTION OF SYMBOLS 1 ... Vehicle, 1a ... Front windshield (transmission reflective surface), 2 ... Eye box, 3 ... Viewpoint, 4 ... Bus, 5 ... Operation part, 6 ... Viewpoint position detection part, 10 ... Image display part, 20 ... Relay optical System 30 30 actuator 40 control unit (actuator control unit, display control unit) 41 processing unit 42 storage unit 43 interface (operation information acquisition means, viewpoint position information acquisition means) 200 virtual image area 201: virtual image C: operation information D: image data G: viewpoint position information K: display light L: relative brightness of virtual image Q: brightness information θ: incident angle

Claims (8)

An image display unit for displaying a display image on a display surface;
A relay optical system which directs the display light of the display image displayed on the display surface by the image display unit to a transmission / reflection surface disposed in front of the user;
The first adjustment mode for adjusting the light intensity of the display light according to the size of the incident angle of the display light with respect to the transmission / reflection surface, and the incidence of the display light for the transmission / reflection surface compared to the first adjustment mode A display control unit capable of controlling the image display unit by switching at least a second adjustment mode of adjusting so that the change rate of the light intensity of the display light with respect to the size of the angle is large ;
Operation information acquisition means for acquiring operation information of the user;
The display control unit adjusts the rate of change in the second adjustment mode based on the operation information input by the operation information acquisition unit.
Head-up display characterized by. The apparatus further comprises an actuator capable of adjusting an incident angle to the transmission / reflection surface by moving or / and rotating at least the relay optical system.
The head-up display according to claim 1, The display control unit adjusts the luminance of the display image according to the display position in the display surface based on the first adjustment mode or the second adjustment mode.
The head up display according to any one of claims 1 or 2, characterized in that: The operation information includes information on the degree of polarization of the sunglasses,
The head up display according to any one of claims 1 to 3 , characterized in that: The information processing apparatus further comprises a determination information acquisition unit that captures an image of the user and acquires wear determination information that determines that the user wears sunglasses.
The display control unit switches from the first adjustment mode to the second adjustment mode based on the wearing determination information input by the determination information acquiring unit.
The head up display according to any one of claims 1 to 4 , characterized in that: The display controller, before Symbol first adjustment mode and the second adjustment mode, adjusts the light intensity of the display light in accordance with the position and / or angle of the relay optical system,
The head up display according to any one of claims 1 to 5 , characterized in that: A viewpoint position information acquisition unit configured to acquire viewpoint position information on a user's vertical viewpoint position;
The display controller, before Symbol first adjustment mode and the second adjustment mode, on the basis of the viewpoint position information the viewpoint position information obtaining means is input, for adjusting the light intensity of the display light,
The head up display according to any one of claims 1 to 6 , characterized in that: The head-up display according to any one of claims 1 to 7 , wherein the display light emitted from the image display unit is non-polarized light.

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