JP2017165293A - Vehicular display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily eliminate an influence of light leakage of a light source for lighting.SOLUTION: A vehicular display device comprises at least: a light source 12 for lighting capable of illuminating a display panel 11; and an illuminance sensor 14 capable of detecting external light illuminance X, and further comprises control means 17 for sending an illumination control signal 16 to the light source 12 for lighting, based on the detected illuminance W from the illuminance sensor 14. The control means 17 determines the illumination control signal 16 based on a detected illuminance W' detected in an off time of the illumination control signal 16.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a vehicle display device.

  Vehicles such as automobiles are provided with various display devices (vehicle display devices) in the passenger compartment. Some of such display devices can automatically adjust the brightness (or luminance) according to the intensity of external light.

  The display device described above includes at least an illumination light source capable of illuminating the display panel and an illuminance sensor capable of detecting the illuminance of external light, and illuminates the illumination light source based on the detected illuminance of external light from the illuminance sensor. And a control means for sending a control signal.

  Examples of such display devices that can automatically adjust the luminance include a head-up display device (see, for example, Patent Document 1). In the head-up display device, the image of the display device is reflected by a reflective member in front of the driver's seat (for example, a dedicated reflector such as a combiner) to form a virtual image on the back side of the reflective member. .

  By providing such a head-up display device, the driver can obtain information that assists driving with a small amount of line-of-sight movement while driving forward.

Japanese Patent Laid-Open No. 2005-14788

However, the above vehicle display device has the following problems.
That is, it is difficult for the display device for a vehicle to completely eliminate the optical influence (for example, light leakage) due to the light source for illumination structurally. Therefore, an error occurs in the detected illuminance of the illuminance sensor due to the influence of light leakage of the illumination light source. As a result, there is a possibility that automatic adjustment of the brightness of the display panel cannot be performed accurately. This is a problem particularly at night when the illuminance of outside light is low and the ratio of light leakage to outside light is large.

  Accordingly, the main object of the present invention is to solve the above-described problems.

In order to solve the above problems, the present invention provides:
At least including an illumination light source capable of illuminating the display panel and an illuminance sensor capable of detecting the illuminance of external light,
In the vehicle display device comprising a control means for sending an illumination control signal to the illumination light source based on the detected illuminance from the illuminance sensor,
The control means obtains the illumination control signal based on a detected illuminance detected when the illumination control signal is turned off.

  According to the present invention, the above configuration can eliminate the influence of light leakage of the illumination light source.

It is a block diagram of the display apparatus for vehicles concerning this Embodiment. It is a disassembled perspective view of the display apparatus for vehicles of FIG. FIG. 2 is a control system diagram of the vehicle display device of FIG. 1. It is a graph which shows the condition of the general detection illumination intensity by an illumination intensity sensor. 6 is a graph in which illumination control signals and detected illuminance are associated with each other vertically. It is a flowchart which controls the display apparatus for vehicles.

Hereinafter, the present embodiment will be described in detail with reference to the drawings.
1 to 6 are for explaining this embodiment.

  <Configuration> The configuration of this embodiment will be described below.

  As shown in FIG. 1 (see also FIG. 2), a display device 1 (vehicle display device) is provided in a vehicle interior of a vehicle such as an automobile. The display device 1 is capable of automatically adjusting the brightness (or luminance) according to the intensity of outside light.

  Examples of the display device 1 that can automatically adjust the brightness include a head-up display device 2. The head-up display device 2 will be described later.

  As shown in FIG. 3, at least the illumination light source 12 that can illuminate the display panel 11 and the illuminance sensor 14 that can detect the illuminance of external light (external light illuminance X, see FIG. 4). And a control means 17 (or a control device) that sends an illumination control signal 16 to the illumination light source 12 based on the detected illuminance W of the external light from the illuminance sensor 14.

  Here, the display panel 11 is a liquid crystal panel or the like. The illumination light source 12 is used as a backlight of a liquid crystal panel. A highly responsive light source such as LED or LD (laser diode) is used for the illumination light source 12. The illumination light source 12 is driven by PWM (Pulse Width Modulation). And the control means 17 is made to output a rectangular wave as the illumination control signal 16 with respect to the light source 12 for illuminations, such as LED and LD (laser diode) (refer FIG. 5). The control means 17 is, for example, a microcomputer including a CPU 21 that performs arithmetic control, an internal memory 22 that stores data and programs, and a dimming arithmetic unit such as a PWM generator 23. In addition, power supply circuits 24 and 25 are connected to the illumination light source 12 and the illuminance sensor 14, respectively. The control means 17 is connected to the power supply circuit 25 of the illumination light source 12 via the switch element 26.

  As shown in FIG. 2, the display panel 11 including the illumination light source 12, the illuminance sensor 14, the control unit 17, and the like are mounted on the substrate 31. The substrate 31 is attached to the lower casing 32 of the display device 1. At this time, since the illumination light source 12 generates a large amount of heat, a heat sink 33 or the like for heat radiation is attached to the back side of the display panel 11. Further, at the upper and lower portions of the display panel 11, an intake gap 34 and an exhaust gap 35 are provided for allowing cooling air to pass through the ventilation space formed between the display panel 11 and the heat sink 33. .

  The upper casing 36 of the display device 1 is provided with an opening 37 for taking in external light. External light taken from the opening 37 is guided to the illuminance sensor 14 through the light guide 38.

  Then, due to the provision of the above-described intake gap 34, exhaust gap 35, and the like, light leakage Y of the illumination light source 12 occurs from there, and the leaked light passes through the light guide 38 and the illuminance sensor. 14, an error corresponding to the amount of light leakage Y occurs in the detected illuminance W of the illuminance sensor 14 (detected illuminance W = external light illuminance X + light leakage Y). It is structurally difficult to prevent light leakage Y from the intake gap 34 and the exhaust gap 35.

  In contrast to the basic configuration as described above, this embodiment has the following configuration.

  (1) The control means 17 obtains the illumination control signal 16 based on the detected illuminance W ′ (= Woff) detected when the illumination control signal 16 is turned off.

  Here, in FIG. 5, the upper part is a graph showing the illumination control signal 16, and the lower part is a graph showing the detected illuminance W of external light. In the figure, the occurrence of light leakage Y (= ΔW) coincides with the ON / OFF cycle of the illumination control signal 16 and occurs only when the illumination control signal 16 is ON. Therefore, when the illumination control signal 16 is off, no light leakage Y occurs (detected illuminance W ′ at off time = external light illuminance X). Therefore, as described above, the detected illuminance W ′ when off is directly detected.

(2) Further, the control means 17 includes a detected illuminance W (= W _on ) detected when the illumination control signal 16 is turned on and a detected illuminance W ′ (= W _off ) detected when the illumination control signal 16 is turned _off . The correction value A may be obtained based on the difference ΔW (= light leakage Y), and the illumination control signal 16 may be corrected by the correction value A.

  Here, the correction value A may be obtained as an average value of a plurality of (n) periods of the illumination control signal 16 (for example, n = 10, but is not limited to 10). Note that the correction value A is appropriately added to or subtracted from the illumination control signal 16, depending on the control method.

  FIG. 6 is a flowchart for correcting the illumination control signal 16 in the night dimming mode.

First, in the night dimming mode, 1 is set to a control variable n for obtaining an average value in step S1. Then, the detected illuminance W _n (light reception energy) when (PWM) is on (T _n ) is detected in step S2, and the detected illuminance W _n (or the voltage V _n obtained by the illuminance sensor 14) is stored in the internal memory 22 in step S3. ) Is memorized.

Next, the detected illuminance W ′ _n (light reception energy) when (PWM) is off (T ′ _n ) is detected in step S4, and the detected illuminance W ′ _n (or the illuminance sensor 14 is obtained in the internal memory 22 in step S5. Stored voltage V ′ _n ).

  Thereafter, 1 is added to the control variable n in step S6, and it is determined in step S7 whether or not the control variable n has reached a predetermined constant (in this case, n = 10).

  And when it has not reached the constant (No), it returns to step S2 and repeats until it reaches.

When the constant is reached (Yes), the average of the difference (V _n −V ′ _n ) for the constant number stored in the internal memory 22 in step S8 is taken as the correction value A.

Then, the illumination control signal 16 is corrected using the correction value A obtained in step S8 (V _out = V _{n + 1} ± A), and the illumination control signal 16 (V _out ) corrected in step S9 is _supplied to the PWM generator 23 or the like. It outputs to the light source 12 for illumination via a light control calculating part.

  As described above, the illumination light source 12 is accurately and automatically adjusted.

  (3) As described above, the display device 1 can constitute the head-up display device 2 capable of displaying (or reflecting projection) the image 42 of the display panel 11 in front of the driver's seat 41. .

  Here, the head-up display device 2 reflects the image 42 of the display panel 11 with a reflection member 43 in front of the driver's seat 41 (for example, a dedicated reflection plate such as a combiner), and the above-described image is formed on the back side of the reflection member 43. A virtual image 44 of the image 42 is formed. The image 42 on the display panel 11 is guided to the reflecting member 43 directly or indirectly through an optical component such as a mirror 45. In this case, the head-up display device 2 is attached to a part of the instrument panel 46 and the virtual image 44 is visually recognized at a position on the back side of the front window 47.

  <Operation> The operation of this embodiment will be described.

  The vehicular display device can automatically adjust the brightness (or luminance) according to the intensity of outside light. In order to automatically adjust the luminance, the control unit 17 obtains an illumination control signal 16 based on the detected illuminance W from the illuminance sensor 14 and sends the illumination control signal 16 to the illumination light source 12. Thereby, the brightness | luminance of the display panel 11 according to the external light illumination intensity X can be adjusted.

  The illumination light source 12 is often an LED or LD (laser diode), and the illumination light source 12 is often driven by PWM (Pulse Width Modulation). The control means 17 outputs a rectangular wave as the illumination control signal 16 to the illumination light source 12 having a high response such as a laser diode.

  At this time, since it is difficult for the display device for a vehicle to completely eliminate the optical influence (for example, the occurrence of light leakage Y) due to the illumination light source 12 due to its structural problem, An error may occur in the detected illuminance W of the illuminance sensor 14 due to the influence of the light leakage Y.

  In particular, at night when the external light illuminance X is low, the ratio of the light leakage Y in the external light illuminance X is large, so the influence of the light leakage Y is large.

  <Effect> According to this embodiment, the following effects can be obtained.

  (Effect 1) The control unit 17 obtains the illumination control signal 16 based on the detected illuminance W ′ detected when the illumination control signal 16 is turned off. Since the occurrence of the light leakage Y coincides with the on / off cycle of the illumination control signal 16, that is, the light leakage Y occurs when the illumination control signal 16 is turned on, the illumination light source 12 is turned off. By detecting when the light leakage Y no longer occurs, the accurate external light illuminance X can be directly detected, and the accurate detection illuminance W of the external light not affected by the light leakage Y of the illumination light source 12 can be obtained. Can be obtained. As a result, the brightness of the display panel 11 can be automatically adjusted more accurately. This is particularly effective at night when the external light illuminance X decreases and the ratio of light leakage Y in the external light increases.

(Effect 2) In the above, the control unit 17 further detects the illuminance W (= W _on ) of the illuminance sensor 14 detected when the illumination control signal 16 is turned on, and the illuminance sensor 14 detected when the illumination control signal 16 is turned off. The correction value A may be obtained based on the difference ΔW from the detected illuminance W ′, and the illumination control signal 16 may be corrected using the correction value A. Since the detected illuminance W (= W _on ) at the time of _on is larger than the detected illuminance W ′ at the time of off by the amount of the light leakage Y, the actual light leakage Y is The quantity can be obtained. Then, by correcting the illumination control signal 16 using the correction value A obtained in this way, the luminance of the illumination light source 12 is reduced by the amount of light leakage Y, for example (depending on the control method). Is increased to make the virtual image 44 have a desired brightness, or when the preceding control is performed to increase the luminance of the illumination light source 12 in anticipation of the light leakage Y, the preceding control becomes excessive. The brightness of the illumination light source 12 can be lowered by a certain amount to make the virtual image 44 have a desired brightness.

Further, since the correction value A is obtained by using the difference (W _on -W _off ) of the detected illuminance when the illumination control signal 16 is turned on and off, a stable correction value A can be obtained regardless of day or night. Can be obtained.

  Furthermore, since the accurate external light illuminance X and the stable correction value A can be obtained by the above, for example, it is possible to eliminate the need to separately provide a correction semiconductor element or the like. In addition, since the external light illuminance X and the correction value A can be easily obtained and can be easily reflected in the illumination control signal 16, as described above (a separately provided semiconductor device for correction) It is possible to eliminate the need for complex feedforward control using correction data (from the above).

  (Effect 3) The head-up display device 2 reflects the image 42 of the display panel 11 with a reflection member 43 in front of the driver's seat 41 (for example, a dedicated reflection plate such as a combiner), and a virtual image behind the reflection member 43. 44 is imaged.

  By providing the head-up display device 2, the driver can obtain information that assists driving with a small amount of line-of-sight movement from the state of driving facing forward.

  Then, by applying to a vehicle display device such as the head-up display device 2, the above-described effects can be obtained for the head-up display device 2.

  While the embodiments have been described in detail with reference to the drawings, the embodiments are merely illustrative. Therefore, the present invention is not limited only to the embodiments, and it goes without saying that design changes and the like within a range not departing from the gist are included in the present invention. Further, for example, when each embodiment includes a plurality of configurations, it is a matter of course that possible combinations of these configurations are included even if not specifically described. Further, when a plurality of embodiments and modification examples are disclosed, it is needless to say that possible combinations of configurations extending over these are included even if not specifically described. Further, the configuration depicted in the drawings is of course included even if not particularly described. Further, when there is a term of “etc.”, it is used in the sense that the equivalent is included. In addition, when there are terms such as “almost”, “about”, “degree”, etc., they are used in the sense that they include those in the range and accuracy recognized by common sense.

DESCRIPTION OF SYMBOLS 1 Display apparatus 2 Head-up display apparatus 11 Display panel 12 Illumination light source 14 Illuminance sensor 16 Illumination control signal 17 Control means 41 Driver's seat 42 Image A Correction value W (When ON) Detected illuminance W 'Detected illuminance at OFF [Delta] W Difference X Light intensity Y Light leakage

Claims (3)

At least including an illumination light source capable of illuminating the display panel and an illuminance sensor capable of detecting the illuminance of external light,
In the vehicle display device comprising a control means for sending an illumination control signal to the illumination light source based on the detected illuminance from the illuminance sensor,
The vehicle display device, wherein the control means obtains the illumination control signal based on a detected illuminance detected when the illumination control signal is turned off. The vehicle display device according to claim 1,
The control means obtains a correction value based on a difference between a detected illuminance detected when the illumination control signal is turned on and a detected illuminance detected when the illumination control signal is turned off, and corrects the illumination control signal by the correction value. A display device for a vehicle characterized by the above. The vehicle display device according to claim 1 or 2, wherein
The display device for vehicles, wherein the display panel constitutes a head-up display device capable of displaying an image in front of a driver's seat.