JP7243183B2 - vehicle mirror - Google Patents

Description

The present disclosure relates to vehicle mirrors.

Patent Literature 1 discloses an electronic mirror device for a vehicle, which has a mirror function that allows the rear of the vehicle to be visually recognized and a display function that displays various information.

JP 2017-47804 A

However, in the prior art as described above, it was necessary to provide a display panel (light source) for realizing the display function separately from the structure for realizing the mirror function.

Therefore, in one aspect, an object of the present invention is to make it possible to realize a display function using a structure for realizing a mirror function.

In one aspect, a vehicle mirror forming a reflective surface for light, comprising:
a first liquid crystal layer provided in the first area, in which the alignment direction of the liquid crystal molecules changes according to the applied voltage;
a first electrode layer provided on the side of the first liquid crystal layer on which external light is incident in the first area;
a first counter electrode layer provided in the first area and facing the first electrode layer via the first liquid crystal layer;
a first front polarizing layer provided closer to the incident side of external light than the first electrode layer in the first area;
a first polarizing layer provided behind the first counter electrode layer in the first area in the incident direction of external light and forming the reflecting surface;
a second liquid crystal layer that is provided in a second area different from the first area and in which the alignment direction of liquid crystal molecules changes according to an applied voltage;
a second electrode layer provided on the side of the second liquid crystal layer on which external light is incident in the second area;
a second counter electrode layer provided in the second area and facing the second electrode layer via the second liquid crystal layer;
a second front polarizing layer provided closer to the incident side of external light than the second electrode layer in the second area;
a second polarizing layer provided behind the second counter electrode layer in the direction of incidence of external light in the second area and forming the reflective surface;
The first electrode layer and the first counter electrode layer are each capable of integrally applying a voltage to the whole,
A vehicle mirror is provided in which at least one of the second electrode layer and the second counter electrode layer can individually apply a voltage to a plurality of electrodes divided for each pixel.

In one aspect, according to the present invention, it is possible to realize a display function using a structure for realizing a mirror function.

It is a top view of the mirror for vehicles of this embodiment. FIG. 2 is a schematic diagram showing a cross section taken along the line AA of FIG. 1; A diagram showing an example of the pattern of the upper electrode part It is a figure which shows an example of the pattern of a lower electrode part. FIG. 3B is a schematic enlarged view of the P portion of FIG. 3B; FIG. 4 is a diagram for explaining the operation of the vehicle mirror of the present embodiment when it is in a mirror mode; FIG. 5 is a diagram schematically showing time-series waveforms of voltages applied to the first area electrode and the upper electrode portion in the antiglare mirror mode; FIG. 4 is a front view schematically showing the state of the vehicle mirror in the display mode; FIG. 4 is a front view schematically showing the state of the vehicle mirror in the display mode; 4 is a block diagram showing an example of main functions of a control board; FIG. It is a figure which shows an example of the relationship between the intensity|strength of glare light, and a reflectance. 4 is a control block diagram of a passive liquid crystal shutter and an active liquid crystal shutter by a reflectance control unit; FIG. FIG. 10 is an explanatory diagram of Modification 1;

Hereinafter, each embodiment will be described in detail with reference to the accompanying drawings. The same numbers or symbols are given to the same elements throughout the description of the embodiment.

FIG. 1 is a plan view of a vehicle mirror 1 of this embodiment, and FIG. 2 is a schematic diagram showing a cross section taken along the line AA of FIG. In FIG. 1, three mutually orthogonal X, Y, and Z directions are defined in a right-handed coordinate system. Hereinafter, the Z direction is the front direction, and in each cross section, the positive side in the Z direction is the upper side and the negative side is the lower side. Thus, for example, a front view means a view in the Z direction. In FIG. 1, the first area B1 and the like are bounded by dotted lines, but the dotted lines are for illustration purposes only and are not substantially visible in practice.

In addition, although this embodiment shows the rearview mirror provided in the vehicle as the vehicle mirror 1, the door mirror etc. which are provided outside the vehicle may be sufficient.

The vehicle mirror 1 includes a bottomed rectangular housing 10 having an opening 10A on the side viewed by the driver, and a transparent cover 11 attached to close the opening 10A of the housing 10 .

As shown in FIG. 1, the vehicle mirror 1 has two areas (hereinafter referred to as a first area B1 and a second area B2) in a region functioning as a mirror. In another embodiment, the vehicle mirror 1 may have three or more areas. The region functioning as a mirror is a region surrounded by the opening 10A in front view.

The first area B1 is an area that occupies most of the entire area, and has a mirror function (anti-glare function) as described later.

The second area B2 is an area extending over a relatively narrow range, and has a display function as well as a mirror function (anti-glare function), as will be described later.

Since the second area B2 has a display function, it is provided at a position that is easy for the user (driver) to see, but does not impede the mirror function. For example, as shown in FIG. 2, the second area B2 has a belt-like shape extending in the left-right direction at the bottom. However, the second area B2 may be provided at other positions such as the left and right ends or the upper part.

(Case 10)
The housing 10 is a portion that accommodates each member described below and forms the appearance of the vehicle mirror 1 .

In FIG. 2, the housing 10 is drawn as an integral type, but the housing 10 need not be limited to an integral type, and may be separable into a plurality of parts.

As shown in FIG. 1, the housing 10 includes, from the bottom, a control substrate 22 (an example of a control unit), a reflective polarizing plate 31 (an example of first and second polarizing layers), and a glass substrate 32. , a polarization control section 33, a glass substrate 34, and a front polarizing plate 35 (an example of the first and second front polarizing layers).

(Control board 22)
A processing device such as a microcomputer is mounted on the control board 22 . The control board 22 forms an ECU (Electronic Control Unit). Further details of the control board 22 will be described later.

(Reflection polarizing plate 31)
The reflective polarizer 31 transmits P-polarized light and reflects S-polarized light. The reflective polarizing plate 31 is not necessarily formed as a plate material with high rigidity, and may be formed as a film material with low rigidity. are using.

In this embodiment, the reflective polarizing plate 31 is not separated between the first area B1 and the second area B2, but is shared. It may be provided in a separate form.

(Glass substrates 32, 34)
Both the glass substrates 32 and 34 are transparent substrates with sufficiently high transmittance for visible light. A lower electrode portion 33B is formed on the upper surface of the glass substrate 32 . An upper electrode portion 33</b>C is formed on the lower surface of the glass substrate 34 .

In this embodiment, the glass substrates 32 and 34 are not separated between the first area B1 and the second area B2, but are common. It may be provided in a form separated from the area B2.

(Polarization control unit 33)
As shown in FIG. 2, the polarization control section 33 includes a liquid crystal layer 33A (an example of first and second liquid crystal layers), a lower electrode section 33B, and an upper electrode section 33C.

In the liquid crystal layer 33A, the alignment direction of the liquid crystal molecules changes according to the applied voltage. The liquid crystal layer 33A may be of any type such as TN liquid crystal.

In the present embodiment, as an example, when the voltage applied to the liquid crystal layer 33A is 0 (V), the alignment direction of the liquid crystal molecules of the liquid crystal layer 33A does not change, and the applied voltage reaches the maximum value. If it is (for example, 5 (V)), the alignment direction of the liquid crystal molecules of the liquid crystal layer 33A changes. The alignment direction of the liquid crystal molecules when the applied voltage is 0 (V) is set so that the light is twisted by 90 degrees (the polarization changes) when passing through the liquid crystal layer 33A. In this embodiment, if the light incident on the liquid crystal layer 33A from the lower side is the second polarized light (S polarized light), the light emitted from the upper side of the liquid crystal layer 33A becomes the first polarized light (P polarized light), and vice versa. If the light incident on the liquid crystal layer 33A from the upper side is the first polarized light (P polarized light), the light emitted from the lower side of the liquid crystal layer 33A becomes the second polarized light (S polarized light).

On the other hand, when the applied voltage is the maximum value (for example, 5 (V)), the alignment direction of the liquid crystal molecules is aligned along the electric field, and the light is twisted (the polarization changes) when passing through the liquid crystal layer 33A. It is set to go straight without That is, when the voltage ΔV applied to the liquid crystal layer 33A is the maximum, if the light incident on the liquid crystal layer 33A is the second polarized light (S-polarized light), the light emitted from the liquid crystal layer 33A is also the second polarized light (S-polarized light). Similarly, if the light incident on the liquid crystal layer 33A is the first polarized light (P polarized light), the light emitted from the liquid crystal layer 33A will also be the first polarized light (P polarized light).

In this embodiment, the liquid crystal layer 33A is not separated between the first area B1 and the second area B2, but is common. It may be provided in separate form.

The lower electrode portion 33B is provided on the reflective polarizing plate 31 side of the liquid crystal layer 33A. Here, in the present embodiment, as described above, the vehicle mirror 1 has the first area B1 and the second area B2. , the configuration of the lower electrode portion 33B is different. That is, the lower electrode portion 33B is provided in a region corresponding to the second area B2 and a first area lower electrode layer 33B1 (an example of a first counter electrode layer) provided in a region corresponding to the first area B1. and a second area lower electrode layer 33B2 (an example of a second counter electrode layer). The lower electrode portion 33B may be formed, for example, on the surface of the glass substrate 32 facing the liquid crystal layer 33A using a transparent electrode material such as ITO.

The upper electrode portion 33C is provided on the front polarizing plate 35 side of the liquid crystal layer 33A. The upper electrode portion 33C may be formed, for example, on the surface of the glass substrate 34 facing the liquid crystal layer 33A using a transparent electrode material such as ITO.

FIG. 3A is a diagram showing an example of the pattern of the upper electrode portion 33C, and FIG. 3B is a diagram showing an example of the pattern of the lower electrode portion 33B.

As shown in FIG. 3A, the upper electrode portion 33C is formed of one common electrode provided over the entire region functioning as a mirror (the entire liquid crystal layer 33A). That is, the upper electrode portion 33C has an electrode portion (an example of a first electrode layer) in a region corresponding to the first area B1 and an electrode portion (an example of a second electrode layer) in a region corresponding to the second area B2. , are common. However, in other embodiments, the upper electrode portion 33C includes an electrode portion (an example of a first electrode layer) in a region corresponding to the first area B1 and an electrode portion (second electrode layer) in a region corresponding to the second area B2. layer) and are separate aspects and may be individually controllable.

As shown in FIG. 3B, the pattern of the lower electrode portion 33B consists of a first area lower electrode layer 33B1 corresponding to the first area B1 and a second area lower electrode layer 33B2 corresponding to the second area B2. different. Specifically, the first area lower electrode layer 33B1 is formed as one electrode, while the second area lower electrode layer 33B2 is formed as a plurality of electrode portions for each pixel (hereinafter referred to as “pixel electrode 330”). ).

FIG. 4 is a schematic enlarged view of part P in FIG. 3B.

Each of the pixel electrodes 330 is provided with a thin film transistor (TFT) as shown in FIG. Voltage is controlled.

More specifically, the second area lower electrode layer 33B2, which is an electrode portion formed by a plurality of pixel electrodes 330, includes, in addition to the pixel electrodes 330, a plurality of gate lines arranged in the Y direction (vertical direction in FIG. 4). , and gate lines so as to form a lattice pattern, the source lines are arranged in the X direction (horizontal direction in FIG. 4), and the gate lines and the source lines are provided for each region surrounded by the gate lines and the source lines. A thin film transistor (TFT) to be connected is provided at least, and the pixel electrode 330 is provided so as to be connected to the thin film transistor for each region surrounded by at least the gate line and the source line.

Note that the plurality of source lines are connected to the corresponding source electrodes of the TFTs, and the plurality of gate lines are connected to the corresponding gate electrodes of the TFTs. The line and the gate line seem to be in contact at the crossing portion, but this portion is formed so as not to short-circuit the source line and the gate line.

Further, each rectangular region partitioned by the source line and the gate line corresponds to a pixel, and the drain electrode of the TFT is connected to the pixel electrode. , pixel electrodes are provided.

The ends of the gate lines are connected to the gate driver 2243 (see FIG. 7) and the ends of the source lines are connected to the source driver 2242 (see FIG. 7). The driver 2243 and the source driver 2242 control the driving of the TFTs, thereby individually controlling the voltages applied to the pixel electrodes 330 .

(Front polarizing plate 35)
The front polarizing plate 35 transmits the first polarized light (P polarized light) and absorbs the second polarized light (S polarized light). The front polarizing plate 35 is not necessarily formed as a plate material with high rigidity, and may be formed as a film material with low rigidity. are using.

In the present embodiment, the front polarizing plate 35 is not separated between the first area B1 and the second area B2, and is shared. It may be provided in a separate form.

(Overall Summary of Vehicle Mirror 1)
Thus, in the vehicle mirror 1, the configuration of the lower electrode portion 33B differs between the first area B1 and the second area B2. Specifically, the polarization control section 33 in the first area B1 forms a passive liquid crystal shutter, and the polarization control section 33 in the second area B2 forms an active liquid crystal shutter. Hereinafter, the polarization control section 33 in the first area B1 is also called "passive liquid crystal shutter 331", and the polarization control section 33 in the second area B2 is also called "active liquid crystal shutter 332".

Next, an operation example of the vehicle mirror 1 and the like will be described in more detail with reference to FIG. 5A and subsequent drawings.

In the present embodiment, as an example, the control substrate 22 has a voltage applied to the liquid crystal molecules of the liquid crystal layer 33A corresponding to the first area B1 and a voltage applied to the liquid crystal molecules of the liquid crystal layer 33A corresponding to the second area B2. , to selectively form the mirror mode and the antiglare mirror mode in the first area B1, and selectively form the display mode, the mirror mode, and the antiglare mirror mode in the second area B2. to form. However, in another embodiment, the control board 22 may always form only the display mode in the second area B2.

(mirror mode)
FIG. 5A is a diagram for explaining the operation of the vehicle mirror 1 of the present embodiment when it is in the mirror mode, and is basically the same as in FIG. is shown in the figure.

First, when no voltage is applied to the liquid crystal layer 33A, that is, when the voltage V1 of the lower electrode portion 33B and the voltage V2 of the upper electrode portion 33C are the same voltage and the voltage difference ΔV is 0 (V), The alignment direction of the liquid crystal molecules in the liquid crystal layer 33A does not change.

At this time, if the light incident on the liquid crystal layer 33A is the second polarized light (S polarized light), the light becomes the first polarized light (P polarized light) when emitted from the liquid crystal layer 33A, and conversely enters the liquid crystal layer 33A. If the light is the first polarized light (P polarized light), the light becomes the second polarized light (S polarized light) when emitted from the liquid crystal layer 33A.

In addition, hereinafter, this voltage difference ΔV is also referred to as the voltage ΔV applied to the liquid crystal layer 33A.

On the other hand, as the voltage ΔV applied to the liquid crystal layer 33A increases, the alignment direction of the liquid crystal molecules of the liquid crystal layer 33A changes. It does not exhibit the function of changing the polarization state.

That is, when the voltage ΔV applied to the liquid crystal layer 33A is the maximum, if the light incident on the liquid crystal layer 33A is the second polarized light (S-polarized light), the light emitted from the liquid crystal layer 33A is also the second polarized light (S-polarized light). Similarly, if the light incident on the liquid crystal layer 33A is the first polarized light (P polarized light), the light emitted from the liquid crystal layer 33A will also be the first polarized light (P polarized light).

As the voltage ΔV applied to the liquid crystal layer 33A increases, if the light incident on the liquid crystal layer 33A is the second polarized light (S-polarized light), the second polarized light (S-polarized light) is emitted from the liquid crystal layer 33A. ) is increasing.

Similarly, as the voltage ΔV applied to the liquid crystal layer 33A increases, if the light incident on the liquid crystal layer 33A is the first polarized light (P polarized light), the light emitted from the liquid crystal layer 33A also becomes the first polarized light. The proportion of light that is (P-polarized) increases.

In the mirror mode, the voltage V1 of the lower electrode portion 33B and the voltage V2 of the upper electrode portion 33C are controlled so that the voltage ΔV applied to the liquid crystal layer 33A is 0 (V).

For example, control is performed such that the voltage V1 of the lower electrode portion 33B is set to 0 (V) and the voltage V2 of the upper electrode portion 33C is set to 0 (V).

Of course, even if the voltage V1 of the lower electrode portion 33B is set to 5 (V) and the voltage V2 of the upper electrode portion 33C is set to 5 (V), the voltage ΔV applied to the liquid crystal layer 33A is 0. Since it becomes (V), there is no problem.

Here, since the external light contains the light of the first polarized light (P polarized light) and the light of the second polarized light (S polarized light) at substantially the same ratio, as shown in FIG. The second polarized light (S-polarized light) is absorbed by the front polarizing plate 35 , and only the first polarized light (P-polarized light) is transmitted through the front polarizing plate 35 .

The light of the first polarized light (P-polarized light) transmitted through the front polarizing plate 35 is incident on the glass substrate 34. Since the glass substrate 34 does not have the function of changing the polarization state, the first polarized light (P-polarized light) The polarized (P-polarized) light is incident on the next liquid crystal layer 33A.

Here, as described above, in the mirror mode, the voltage ΔV applied to the liquid crystal layer 33A is 0 (V). When the 1-polarized light (P-polarized light) exits the liquid crystal layer 33A, it changes to the 2nd-polarized light (S-polarized light). It has become.

Therefore, the light is reflected by the reflective polarizing plate 31 and enters the liquid crystal layer 33A again. The light is the first polarized light (P polarized light).

Therefore, the light emitted from the liquid crystal layer 33 A is transmitted through the glass substrate 34 and then through the front polarizing plate 35 , and is irradiated to the outside of the vehicle mirror 1 through the cover 11 .

In this way, in the mirror mode, the first polarized light (P-polarized light) of the external light is reflected, thus functioning as a mirror.

(anti-glare mirror mode)
FIG. 5B is a diagram schematically showing time-series waveforms of voltages applied to the first area lower electrode layer 33B1 and the upper electrode portion 33C in the antiglare mirror mode.

In the anti-glare mirror mode, the first area B1 passes through the front polarizing plate 35, unlike in the mirror mode, in order to prevent the driver from being dazzled by the reflected light of the headlights of the following vehicle. The first polarized light (P-polarized light) is not always irradiated to the outside of the vehicle mirror 1 .

Specifically, in this embodiment, the vehicle mirror 1 can measure the amount of light emitted from the headlights of the following vehicle toward the vehicle mirror 1 at a position other than the cover 11. A light amount sensor 90 (described later) is provided at a position, and control (automatic anti-glare control) is performed to adjust the voltage ΔV applied to the liquid crystal layer 33A according to the light amount (light intensity) detected by the light amount sensor 90. will be

Specifically, in the anti-glare mirror mode, as shown in FIG. 5B, the first area lower electrode layer 33B1 and A positive voltage and a negative voltage are alternately applied to the upper electrode portion 33C for each frame, and the difference between them is the voltage ΔV. At this time, the predetermined voltage is varied between 0 (V) and a maximum value Vmax (for example, 5 (V)) according to the intensity of the glare light.

For example, when the amount of light emitted from the headlights of the following vehicle toward the vehicle mirror 1 is large and the amount of external light incident on the vehicle mirror 1 is large, the liquid crystal layer Control is performed to increase the voltage ΔV applied to 33A.

Then, as explained in the mirror mode, in the first area B1, as the voltage ΔV applied to the liquid crystal layer 33A increases, the liquid crystal layer 33A does not exhibit the function of changing the polarization state of light. In the mirror mode, most of the light reaching the reflective polarizing plate 31 was reflected. It passes through the reflective polarizing plate 31 and goes to the control substrate 22 side.

Since there is no structure for reflecting light on the side of the control board 22, the light transmitted through the reflective polarizing plate 31 and directed toward the control board 22 does not return to the side of the reflective polarizing plate 31 again.

In addition, even if the second polarized light (S polarized light) is reflected by the reflective polarizing plate 31 and enters the liquid crystal layer 33A again, it is converted to the first polarized light (P polarized light) in the process of passing through the liquid crystal layer 33A. Only a part of the light whose polarization state is changed to the first polarized light (P-polarized light) is transmitted through the front polarizing plate 35 and passes through the cover 11 to the outside of the vehicle mirror 1 . is irradiated to

Thus, in the anti-glare mirror mode, in the first area B1, part of the light of the first polarized light (P-polarized light) of the external light that has passed through the front polarizing plate 35 is reflected, resulting in a vehicular Since the light is emitted to the outside of the mirror 1, the amount of light emitted from the vehicle mirror 1 to the outside is reduced, and the driver can be prevented from being dazzled.

If the amount of light emitted from the vehicle mirror 1 to the outside is attenuated too much, the function of the mirror will not be fulfilled. , the vehicle mirror 1 is controlled so that the vehicle mirror 1 can irradiate the light to the outside. A more detailed example of automatic anti-glare control will be described later with reference to FIGS. 6A and 6B.

(Display mode)
5C and 5D are front views schematically showing the state of the vehicle mirror 1 in the display mode. FIG. 5C shows the first area B1 in the mirror mode, and FIG. 5D shows the first area B1. indicates the anti-glare mirror mode.

In the display mode, information is displayed in the second area B2. The type (attribute) of information to be displayed is arbitrary, and may be vehicle information (for example, vehicle speed, mileage, eco-driving index, etc.) displayed on a meter, or time (see FIGS. 5C and 5D). ) and weather (see FIG. 5D), or information such as e-mail and audio. Hereinafter, information displayed in the second area B2 in the display mode is also referred to as "simple information".

Considering the limited area of the second area B2, the simple information preferably has a relatively small amount of information. For example, simple information includes at least one of characters and symbols.

The simple information is formed by utilizing the difference in reflectance in pixel units (pixel regions) corresponding to the pixel electrodes 330 . That is, as described above, the reflectance of the second area B2 is variable for each pixel due to the pixel electrode 330. Therefore, by appropriately setting the reflectance for each pixel, an image can be formed with contrast. For example, a pixel region whose reflectance is set to the maximum controllable value is in a mirror state, while a pixel region whose reflectance is set to the minimum controllable value is in a transparent state. Simple information (image) can be formed in the second area B2 by utilizing the fact that such a difference can be formed for each pixel.

Note that when the first area B1 is in the mirror mode, as shown in FIG. 5C, there is no contrast between the first area B1 and the second area B2, and the continuity as a whole is enhanced. On the other hand, when the first area B1 is in the anti-glare mirror mode, contrast occurs between the first area B1 and the second area B2, as shown in FIG. emphasized.

In this embodiment, the transparent pixel area is the pixel area that forms the character, but the reverse is also possible. That is, character information or the like may be formed by the contrast between the pixel area in the mirror state and the surrounding transparent pixel area.

(Detailed example of control board 22)
FIG. 6A is a block diagram showing an example of main functions of the control board 22. As shown in FIG. A light amount sensor 90 , a sunlight sensor 92 , an automatic anti-glare switch 94 , and a display mode switch 98 are electrically connected to the control board 22 . Note that the control board 22 may acquire information from electronic components (for example, a radar sensor, etc.) in the vehicle via an appropriate bus such as CAN (Controller Area Network).

The light amount sensor 90 is light amount detection means that generates an electrical signal corresponding to the amount of incident light. The light intensity sensor 90 may be, for example, a photodiode. The light quantity sensor 90 is provided rearward so as to measure the quantity of light from the headlights of the vehicle behind. For example, the light intensity sensor 90 may be embedded in the frame portion 10a of the housing 10 (see FIG. 1).

The electrical signal output by the light amount sensor 90 represents the amount of light (external light) incident on the vehicle mirror 1 . An electrical signal output by the light amount sensor 90 is input to the control board 22 as outside light amount information. The control board 22 controls the passive liquid crystal shutter 331 and the like based on the external light amount information from the light amount sensor 90 . Specifically, the outside light amount information from the light amount sensor 90 can be used for automatic anti-glare control for reducing glare caused by headlight light (outside light) from a vehicle behind the vehicle reflected by the vehicle mirror 1 .

The sunshine sensor 92 is light amount detection means for generating an electrical signal corresponding to the amount of incident light, like the light amount sensor 90, and may be, for example, a photodiode. Unlike the light amount sensor 90, the sunshine sensor 92 may be provided, for example, on the front side of the vehicle mirror 1 so as not to be affected by the light from the headlights of the vehicle behind.

The automatic anti-glare switch 94 is a switch for switching the ON/OFF state of the automatic anti-glare control, and can be operated by the user. The automatic antiglare switch 94 may be provided, for example, on the side of the housing 10 of the vehicle mirror 1 .

The display mode switch 98 is a switch for switching the ON/OFF state of the display mode, and can be operated by the user. The display mode switch 98 may be provided, for example, on the side of the housing 10 of the vehicle mirror 1 . Display mode switch 98, along with auto-dimming switch 94, may be embodied as a mode switch.

The control board 22 includes an ambient light information acquisition section 220 , a mode determination section 222 , a simple information source acquisition section 223 , a reflectance control section 224 and a storage section 228 . The ambient light information acquisition unit 220, the mode determination unit 222, the simple information source acquisition unit 223, and the reflectance control unit 224 are controlled by, for example, a CPU (Central Processing Unit, not shown) mounted on the control board 22. It can be realized by executing a program in a storage device (not shown, for example, ROM (Read Only Memory)) mounted on the substrate 22 . The storage unit 228 can be realized by a storage device (not shown, for example, ROM) mounted on the control board 22 .

The ambient light information acquisition unit 220 acquires ambient light information representing the amount of ambient light from the sunshine sensor 92 . Note that in another embodiment, the ambient light information acquisition unit 220 may acquire ambient light information representing the amount of ambient light from an image sensor. In this case, the image sensor may be a dedicated image sensor or an image sensor used for other purposes.

The mode determination unit 222 determines the state of the vehicle mirror 1 based on the on/off state of the automatic anti-glare switch 94 , the on/off state of the display mode switch 98 , and the ambient light information from the ambient light information acquisition unit 220 . Determines the control mode (control state). In this embodiment, as an example, as described above, in the first area B1, the control mode is switched between two modes (mirror mode and antiglare mirror mode), and in the second area B2, three modes (mirror mode, display mode, and anti-glare mirror mode) (determine which mode).

Specifically, the mode determination unit 222 selects the control mode for both the first area B1 and the second area B2 when the automatic anti-glare control is in the off state and the display mode switch 98 is in the off state in "daytime". Select “Mirror Mode”. In this case, the reflectance control section 224 controls both the first area B1 and the second area B2 to the mirror state.

If the automatic anti-glare control is off and the display mode switch 98 is on in the "daytime", the mode determination unit 222 determines the control mode of the first area B1 to be the "mirror mode" and the second area B2. 's control mode is set to "display mode". In this case, the reflectance control unit 224 controls the first area B1 to a mirror state and displays information in the second area B2. A method of displaying information in the second area B2 in the display mode will be described later.

In addition, when the automatic anti-glare control is on and the display mode switch 98 is off in the "daytime", the mode determining unit 222 sets the control mode to "mirror mode" for both the first area B1 and the second area B2. ”. In this case, the reflectance control section 224 controls both the first area B1 and the second area B2 to the mirror state.

Further, when the automatic anti-glare control is on and the display mode switch 98 is on in the "daytime", the mode determining unit 222 determines the control mode of the first area B1 to be the "mirror mode". The control mode of area B2 is determined to be "display mode". In this case, the reflectance control unit 224 controls the first area B1 to the mirror state, and displays the simple information in the second area B2.

In addition, when the automatic anti-glare control is turned off and the display mode switch 98 is turned off in the "nighttime" mode, the mode determination unit 222 sets the control mode to "mirror mode" while controlling both the first area B1 and the second area B2. ”. In this case, the reflectance control section 224 controls both the first area B1 and the second area B2 to the mirror state.

Further, when the automatic anti-glare control is turned off and the display mode switch 98 is turned on in the "nighttime" mode, the mode determination unit 222 determines the control mode of the first area B1 to be the "mirror mode". The control mode of area B2 is determined to be "display mode". In this case, the reflectance control unit 224 controls the first area B1 to the mirror state, and displays the simple information in the second area B2. However, considering that the simplified display is difficult to see at night (because the contrast difference is small), the control mode may be set to "mirror mode" for both the first area B1 and the second area B2.

In addition, when the automatic anti-glare control is on and the display mode switch 98 is off in "nighttime", the mode determination unit 222 sets both the first area B1 and the second area B2 to the "anti-glare control mode". Select “Mirror Mode”. In this case, the reflectance control unit 224 controls both the first area B1 and the second area B2 to the antiglare mirror state.

Further, when the automatic anti-glare control is on and the display mode switch 98 is on at "nighttime", the mode determination unit 222 determines the control mode of the first area B1 to be "anti-glare mirror mode", The control mode of the second area B2 is determined to be "display mode". In this case, the reflectance control unit 224 controls the first area B1 to the anti-glare mirror state, and displays simple information in the second area B2. However, considering that the simple display is difficult to see at night, both the first area B1 and the second area B2 may be set to the "anti-glare mirror mode" as the control mode.

Note that "daytime" and "nighttime" are periods determined in relation to the amount of ambient light. "Nighttime" is a period in which the amount of ambient light is relatively low (a period in which the surroundings are relatively dark). Note that “daytime” and “nighttime” can be determined based on the amount of ambient light and a predetermined threshold value for determining daytime and nighttime. In this case, if the amount of ambient light is greater than the threshold for determining day/night, it is determined to be "daytime", and if the amount of ambient light is less than the threshold for determining day/night, it is determined to be "nighttime". may be judged. The amount of ambient light can be calculated based on the ambient light information from the ambient light information acquisition section 220 .

The simple information source acquisition unit 223 acquires a simple information source for outputting the simple information described above. For example, if the simple information is time or weather, the simple information source acquisition unit 223 acquires time information or weather information from other electronic components as a simple information source via CAN, for example.

The reflectance control unit 224 receives the mode determined by the mode determination unit 222, the ambient light information from the ambient light information acquisition unit 220, the external light amount information from the light amount sensor 90, and the simple information source acquisition unit 223. The voltage applied to the upper electrode portion 33C and the lower electrode portion 33B is controlled based on the simple information source.

Specifically, the reflectance control unit 224 executes automatic anti-glare control in the anti-glare mirror mode and display generation control in the display mode.

(automatic anti-glare control)
When the mode determined by the mode determination unit 222 is the “anti-glare mirror mode,” the reflectance control unit 224 performs automatic anti-glare control based on the outside light amount information from the light amount sensor 90 . The on/off state of the automatic anti-glare control can be switched by the user as described above, and can be switched by operating the automatic anti-glare switch 94 .

When performing automatic anti-glare control, for example, the reflectance control unit 224 determines the intensity of the glare light based on the outside light amount information from the light amount sensor 90 and the ambient light information representing the amount of ambient light from the sunshine sensor 92. The reflectance (control target value) of the vehicle mirror 1 is determined according to . For example, the reflectance (control target value) of the vehicle mirror 1 is determined according to the intensity of the glare so that the relationship (the relationship between the intensity of the glare and the reflectance) shown in FIG. 6B is obtained. FIG. 6B shows a curve 600 of the reflectance (control target value) of the vehicle mirror 1 according to the glare light intensity, with the horizontal axis representing the glare light intensity and the vertical axis representing the reflectance. In this case, the reflectance (control target value) of the vehicle mirror 1 is set to the maximum value (corresponding to the mirror state) until the intensity of the glare exceeds the threshold Th1. , the reflectance (control target value) of the vehicle mirror 1 is gradually reduced toward the minimum value (corresponding to the transmission state, for example, about 10%). Note that the relationship as shown in FIG. 6B is pre-stored in the storage unit 228 as map information. The intensity of the glare light may be calculated based on the outside light amount information from the light amount sensor 90 and the ambient light information indicating the amount of ambient light from the sunshine sensor 92, or may be calculated based on the outside light amount from the light amount sensor 90. It may be calculated based on the information.

After determining the control target value in this manner, the reflectance control unit 224 controls the voltage ΔV applied to the liquid crystal layer 33A in the first area B1 so as to achieve the control target value. As will be described later with reference to FIG. 7, the same applies to the case where the automatic anti-glare control is performed on the second area B2. The voltage ΔV applied to layer 33A is controlled.

(Control block diagram for display generation control, etc.)
FIG. 7 is a control block diagram of the passive liquid crystal shutter 331 and the active liquid crystal shutter 332 by the control board 22 (reflectance control section 224). Here, as an example, the simple information is character information, and the character data signal is generated based on the simple information source.

As shown in FIG. 7, the reflectance control section 224 includes a timing controller 2241, a source driver 2242, a gate driver 2243, and a common driver 2244 as a liquid crystal shutter control section.

The timing controller 2241 sets the application timing of the voltage (signal) to each electrode (the upper electrode section 33C and the lower electrode section 33B) forming the passive liquid crystal shutter 331 and the active liquid crystal shutter 332. The timing controller 2241 controls the gate A data capture timing signal is transmitted to the driver 2243 , a common timing signal is transmitted to the common driver 2244 , and a source timing signal is transmitted to the source driver 2242 .

The source driver 2242 applies a voltage to each source line of the active liquid crystal shutter 332 at timing according to the source timing signal. In display mode, the source driver 2242 applies a voltage according to the character data signal. For example, 0 (V) is applied to the pixel electrodes 330 associated with the pixel regions in which characters are formed, and the maximum value Vmax (eg, 5 ( V)) is applied.

Note that in the mirror mode, the source driver 2242 applies a voltage corresponding to the common signal to each source line of the active liquid crystal shutter 332 . Also, in the antiglare mirror mode, the source driver 2242 applies a voltage corresponding to the antiglare signal to each source line of the active liquid crystal shutter 332 . The voltage (control target value) corresponding to the antiglare signal is varied between 0 (V) and the maximum value Vmax (eg, 5 (V)) according to the intensity of the glare light, as described above.

The gate driver 2243 applies a voltage to each gate line of the active liquid crystal shutter 332 at a timing corresponding to the data capture timing signal, thereby transferring charges corresponding to the voltage applied to the corresponding source line to the pixel electrode 330. Store in a capacitor (not shown). Thereby, for example, in the display mode, a voltage corresponding to the character data signal is applied to the capacitor (not shown) of the pixel electrode 330 . That is, the voltage (character data signal) applied to the corresponding source line is applied to the corresponding pixel electrode 330 . The gate driver 2243 applies a voltage to each gate line of the active liquid crystal shutter 332 in a scanning mode.

In the mirror mode, the gate driver 2243 always keeps the TFTs in the ON state by constantly applying voltage to each gate line. Therefore, in the mirror mode, in the active liquid crystal shutter 332, the voltage ΔV between the upper electrode portion 33C and the second area lower electrode layer 33B2 is always 0 (V), and the mirror state is realized. Also in the anti-glare mirror mode, the gate driver 2243 always keeps the TFTs in the ON state by constantly applying a voltage to each gate line. Therefore, in the anti-glare mirror mode, in the active liquid crystal shutter 332, the voltage ΔV between the upper electrode portion 33C and the second area lower electrode layer 33B2 is always a value corresponding to the anti-glare signal, and the anti-glare state is maintained. Realized.

The common driver 2244 applies the area control signal and the common control signal to the passive liquid crystal shutter 331 and the active liquid crystal shutter 332 at timing according to the common timing signal. In the anti-glare mirror mode, the area control signal and the common control signal applied to the passive liquid crystal shutter 331 have waveforms with opposite polarities and a predetermined amplitude. The predetermined amplitude (control target value) is varied between 0 (V) and the maximum value Vmax (eg, 5 (V)) according to the intensity of the glare light, as described above. Also, in the mirror mode, both the area control signal and the common control signal applied to the passive liquid crystal shutter 331 are set to 0 (V).

According to this embodiment, as described above, simple information can be displayed on the vehicle mirror 1 without using a light source (including the backlight of the display panel, etc.). Specifically, the display function can be realized by using the structure for realizing the mirror function (that is, the active liquid crystal shutter 332). As a result, the vehicle mirror 1 can be provided at a low cost and with high convenience as compared with the case where the light source (including the backlight of the display panel, etc.) is provided separately. In addition, the thickness in the vertical direction can be reduced as compared with the case where a light source (including a backlight of a display panel, etc.) is provided separately.

Further, according to the present embodiment, as described above, the active liquid crystal shutter 332 is not used for the entire region that functions as a mirror, but only a portion of the region functions as a mirror in the mirror mode. can increase This is because, as described above, the mirror state can also be realized in the second area B2 (active liquid crystal shutter 332), but the gaps (boundaries) between the large number of pixel electrodes 330 slightly impair the mirror performance. be. In other words, by using the active liquid crystal shutter 332 for the entire area functioning as a mirror, it is possible to display simple information in the second area without using a light source (including the backlight of the display panel, etc.). With such a configuration, the mirror performance in the first area is inferior to that of this embodiment. In this manner, according to the present embodiment, it is possible to improve convenience by displaying simple information in the second area while maintaining good mirror performance in the first area.

(Modification 1)
In the above embodiments, liquid crystal molecules that align in the same direction when a voltage is applied are used, but liquid crystal molecules that align in the same direction when no voltage is applied may be used. . Such a modified example will be described with reference to FIG.

FIG. 8 is an explanatory diagram of a case where liquid crystal molecules of a type in which the alignment directions are aligned when no voltage is applied is used, and is a schematic diagram showing a cross section along line AA of FIG. 1 in the case of this modification. be. In the vehicle mirror 1A of the modified example shown in FIG. They are different in that they are replaced in section 330 .

The reflective polarizer 310 has a property of transmitting S-polarized light and reflecting P-polarized light.

The polarization control section 330 includes a lower electrode section 33B and an upper electrode section 33C, as in the above-described embodiments. Similarly, in this modification, the area functioning as a mirror is divided into two areas, the first area B1 and the second area B2, so that the lower electrode part 33B is located in the first area B1. A first area lower electrode layer 33B1 (an example of a second electrode portion) provided in a corresponding region, and a second area lower electrode layer 33B2 (a first electrode portion) provided in a region corresponding to the second area B2. ) and two area electrodes.

The polarization control section 330 includes a liquid crystal layer 330A in addition to the lower electrode section 33B and the upper electrode section 33C. The liquid crystal layer 330A includes a type of liquid crystal molecules that are oriented in the same direction when no voltage is applied.

For example, in the mirror mode, referring to FIG. 8, in this modified example, when no voltage is applied to the liquid crystal molecules of the liquid crystal layer 330A (when the voltage ΔV is 0 (V)), light is emitted from the liquid crystal. The alignment direction of the liquid crystal molecules of the liquid crystal layer 330A is set so that the polarization state does not change when the light is transmitted through the layer 330A.

Since the external light contains P-polarized light and S-polarized light at substantially the same ratio, as shown in FIG. 35, the P-polarized light passes through the front polarizing plate 35 and enters the liquid crystal layer 330A.

As described above, in the mirror mode, all the liquid crystal molecules of the liquid crystal layer 330A are oriented in a direction that does not change the polarization state of light. reaches the reflective polarizing plate 310 while being P-polarized.

Then, the P-polarized light that has passed through the liquid crystal layer 330A is reflected by the reflective polarizing plate 310 and enters the liquid crystal layer 330A again. The light is output, transmitted through the front polarizing plate 35 without being blocked by the front polarizing plate 35 , and irradiated to the outside through the cover 11 .

Although the description of the anti-glare mirror mode and the like is omitted, the same effects as those of the above-described embodiment can be obtained in this modified example as well.

Although each embodiment has been described in detail above, it is not limited to a specific embodiment, and various modifications and changes are possible within the scope described in the claims. It is also possible to combine all or more of the constituent elements of the above-described embodiments.

For example, in the above-described embodiments, the configurations of the upper electrode portion 33C and the lower electrode portion 33B may be reversed. That is, the upper electrode portion 33C may have the configuration as shown in FIG. 3B, and the lower electrode portion 33B may have the configuration as shown in FIG. 3A.

Further, in the above-described embodiment, the first area lower electrode layer 33B1 in the first area B1 is one electrode, but it may be an electrode divided into two or more. For example, when the light amount sensor 90 is arranged below the reflective polarizing plate 31, the first area lower electrode layer 33B1 may be divided so that the area overlapping the light amount sensor 90 in a front view is separated from other areas. good. In this case, the electrode portion of the first area lower electrode layer 33B1 that overlaps the light amount sensor 90 in front view may be in a transparent state in the anti-glare mirror mode, and in a mirror state in the mirror mode.

In addition, in the above-described embodiment, in the automatic anti-glare control, the reflectance is varied in multiple steps according to the intensity of the glare light based on the relationship shown in FIG. 6B, but the present invention is not limited to this. . For example, as a simple configuration, when a vehicle behind is detected at night, the reflectance may be reduced compared to when a vehicle behind is not detected. In this case, the vehicle behind may be detected depending on whether the amount of light (light intensity) detected by the light amount sensor 90 exceeds a predetermined threshold, or may be detected by a rear radar sensor or the like.

1 vehicle mirror 10 housing 10A opening 11 cover 20 image display unit 21 case 21A opening 22 control substrate 31 reflective polarizing plate 32 glass substrate 33 polarization control unit 33A liquid crystal layer 33B lower electrode unit 33B1 first area lower electrode Layer 33B2 Second area lower electrode layer 33C Upper electrode portion 34 Glass substrate 35 Front polarizing plate 90 Light sensor 92 Sunlight sensor 94 Automatic anti-glare switch 98 Display mode switch 220 Ambient light information acquisition unit 222 Mode determination unit 223 Simple information source acquisition Unit 224 Reflectance control unit 228 Storage unit 330 Pixel electrode 331 Passive liquid crystal shutter 332 Active liquid crystal shutter B1 First area B2 Second area

Claims (5)

A vehicle mirror that forms a light reflecting surface,
a first liquid crystal layer provided in the first area, in which the alignment direction of the liquid crystal molecules changes according to the applied voltage;
a first electrode layer provided on the side of the first liquid crystal layer on which external light is incident in the first area;
a first counter electrode layer provided in the first area and facing the first electrode layer via the first liquid crystal layer;
a first front polarizing layer provided closer to the incident side of external light than the first electrode layer in the first area;
a first polarizing layer provided behind the first counter electrode layer in the first area in the incident direction of external light and forming the reflecting surface;
a second liquid crystal layer that is provided in a second area different from the first area and in which the alignment direction of liquid crystal molecules changes according to an applied voltage;
a second electrode layer provided on the side of the second liquid crystal layer on which external light is incident in the second area;
a second counter electrode layer provided in the second area and facing the second electrode layer via the second liquid crystal layer;
a second front polarizing layer provided closer to the incident side of external light than the second electrode layer in the second area;
a second polarizing layer provided behind the second counter electrode layer in the direction of incidence of external light in the second area and forming the reflective surface;
The first electrode layer and the first counter electrode layer are each integrally capable of applying a voltage to the whole,
one of the second electrode layer and the second counter electrode layer is composed of a plurality of electrodes divided for each pixel, and a voltage can be applied individually for each pixel;
A vehicle mirror, wherein the vehicle mirror does not have a separately provided light source. a first glass substrate on which the first electrode layer and the second electrode layer are formed;
Further comprising a second glass substrate on which the first counter electrode layer and the second counter electrode layer are formed,
The first front polarizing layer and the second front polarizing layer are made of a common polarizing plate,
The first polarizing layer and the second polarizing layer are made of a common reflective polarizing plate,
2. The vehicle mirror according to claim 1, wherein said first liquid crystal layer and said second liquid crystal layer are a common liquid crystal layer. 3. The vehicle mirror according to claim 2, wherein the first electrode layer and the second electrode layer or the first counter electrode layer and the second counter electrode layer are common electrode layers. controlling the voltage applied to the first electrode layer and the first counter electrode layer so that the first area is in a mirror state or an anti-glare control state, and information is displayed in the second area; 4. The vehicle mirror according to any one of claims 1 to 3, further comprising a control section for controlling voltages applied to said second electrode layer and said second counter electrode layer. 5. The vehicle mirror of claim 4, wherein the information includes at least one of letters and symbols.

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