JP4348061B2 - Device capable of switching between image display state and mirror state, and device equipped with the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a display device with a mirror function capable of switching a display screen to a mirror and a device including the same, or a mirror with an image display function capable of switching a mirror to an image display screen and a device including the mirror.
[0002]
[Prior art]
As a display device (or a mirror having a display function) that can be switched to a mirror state that reflects external light, for example, as described in JP-A-11-15392, JP-A-11-291817, and the like, A display device in which a half mirror material is arranged on the front surface of an image display member such as a liquid crystal display device is known. In these display devices, when the illumination device is turned off or when the image is darkly displayed, the external light reflected by the half mirror material is larger than the image light transmitted through the half mirror material, and therefore, the display device is in a mirror state. On the other hand, when the lighting device is turned on or when the image is brightly displayed, the image light transmitted through the half mirror material is more than the external light reflected by the half mirror material, so that the image display state is established. That is, in these display devices, the same observation plane can be switched between the mirror state and the image display state by switching the brightness of the image display member on the back of the half mirror material.
[0003]
In addition, the republication publication of International Publication No. WO99 / 04315 discloses a liquid crystal display device that can be switched between a shutter open state in which image display is observed and a shutter closed state in which image display is not observed. According to this publication, when the shutter is closed, the external light is reflected and becomes “metal-like”.
[0004]
The liquid crystal display device disclosed in the republished publication of WO99 / 04315 has two liquid crystal display panels in which a liquid crystal layer is sealed in a gap between a pair of substrates provided with electrodes, and an upper surface of the two stacked liquid crystal display panels; Polarizing plates are arranged at three positions between the lower surface and the two liquid crystal display panels. Among these polarizing plates, as the polarizing plate disposed between the liquid crystal display panels, a reflective polarizing plate that transmits predetermined linearly polarized light and reflects linearly polarized light whose polarization axis is orthogonal thereto is used. The transmission polarization axis of the reflective polarizing plate is parallel to the transmission polarization axis of the polarizing plate on the upper surface of the two stacked liquid crystal display panels. As the upper (observer side) liquid crystal display panel, twisted nematic liquid crystal is used as the liquid crystal. In such a configuration, when the voltage applied to the liquid crystal layer of the upper liquid crystal display panel is small, the light transmitted through the upper polarizing plate is reflected with the polarization direction rotated by 90 degrees when transmitted through the liquid crystal layer. Since it reaches the polarizing plate, it is strongly reflected by the reflection characteristics of the reflective polarizing plate. As a result, a “metal tone” shutter is closed. On the other hand, when the voltage applied to the liquid crystal layer of the upper liquid crystal display panel is large, the upper polarizing plate, the upper liquid crystal display panel, and the reflective polarizing plate are effectively transparent, and the lower liquid crystal display The shutter is opened so that the image display on the panel is observed. That is, a shutter closed state in which external light is reflected and exhibits a “metal tone” and a shutter open state in which the display of the lower liquid crystal display panel is observed can be switched by the overvoltage applied to the upper liquid crystal display panel. .
[0005]
[Problems to be solved by the invention]
The above conventional display device can be switched to a mirror-like state that reflects external light, but this mirror-like state is to be used as a mirror for observing a person's face and figure. It is insufficient. This will be specifically described below.
[0006]
Since the display devices disclosed in Japanese Patent Laid-Open Nos. 11-15392 and 11-291817 use a half mirror, the brightness of the mirror state that reflects external light depends on the reflectance of the half mirror. For this reason, in order to make a bright mirror that can be used as a mirror to show a person's face and figure, it is necessary to increase the reflectance of the half mirror. However, when the reflectance of the half mirror is increased, the amount of light of the image is reduced by the amount of light reflected by the half mirror material in the image display state, and thus the display image becomes dark. That is, since the brightness of the image in the image display state and the brightness of the mirror in the mirror state are in a trade-off relationship, it is difficult to achieve both a bright image display and a bright mirror. For this reason, it is difficult to increase the brightness of the mirror state of a display device using a half mirror to such an extent that a person can use it as a mirror to observe his / her face and figure.
[0007]
Further, in such a display device using a half mirror, when used in a bright environment, a part of external light is reflected by the half mirror even in an image display state. For this reason, in the image display state, image quality is deteriorated such as reflection of external light and reduction of the contrast ratio of the image due to reflection of external light.
[0008]
In addition, the display device of the republication publication of the above-mentioned International Publication No. WO99 / 04315 has the following problems when the function of reflecting external light is made to function as a mirror for observing a person's face and figure. Arise.
[0009]
In this display device, when the voltage applied to the liquid crystal layer of the upper (observer side) liquid crystal panel of the two liquid crystal panels is small, the “metal tone” shutter is closed. At this time, light incident from the outside passes through the polarizing plate on the upper surface, passes through the liquid crystal layer of the upper liquid crystal panel, is reflected by the reflective polarizing plate, and returns to the outside again. Thereby, reflection like a mirror is exhibited. On the other hand, of the image display light emitted from the lower liquid crystal panel, the light whose polarization state is controlled as the dark display portion light is because the transmission polarization axis and the polarization axis of the reflective polarizing plate are orthogonal to each other. The light is reflected by this reflective polarizing plate and is not emitted to the outside. However, in reality, since there is no perfect reflection type polarizing plate having a reflectance of 100% in the direction orthogonal to the transmission polarization axis, some dark display portion light is transmitted through the reflection type polarizing plate. The dark display light that has passed through the reflective polarizing plate passes through the liquid crystal layer of the upper liquid crystal panel, so that the polarization axis coincides with the transmitted polarizing axis of the upper polarizing plate, so that it passes through this and is visually recognized by the observer. The That is, when the shutter is in the mirror state, light leaks from the dark display portion of the image to the outside.
[0010]
Of the image display light emitted from the lower liquid crystal panel, the light whose polarization state is controlled as bright display light has a polarization axis parallel to the transmission polarization axis of the reflective polarizing plate. Transmits through the liquid crystal layer of the upper liquid crystal panel. At this time, since the polarization axis rotates by 90 degrees, the polarization axis is orthogonal to the upper polarizing plate and is absorbed by the upper polarizing plate. As is generally known, when liquid crystal molecules are continuously twisted in the layer thickness direction and light is emitted through the liquid crystal layer, depending on the tilt of the liquid crystal molecules in the layer thickness direction and the twisted state, Since the polarization state of the light emitted in the oblique direction of the liquid crystal layer is different, the light emitted in the oblique direction includes a polarization component parallel to the transmission polarization axis of the polarizing plate on the upper surface. For this reason, more light leaks from an oblique direction than the front direction of the display device and is visually recognized by an observer.
[0011]
FIG. 44 shows the result of measurement of light leakage in the shutter closed state by the inventors actually creating a display device substantially similar to the display device of the republication publication of International Publication No. WO99 / 04315. The graph of FIG. 44 shows that the brightness is 450 cd / m in the bright display portion when the display device displays an image with the shutter open. ² Is obtained by measuring light leakage from the front surface of the display device with the lower liquid crystal panel displaying an image and with the upper liquid crystal panel closed in the shutter state. The horizontal axis in FIG. 44 indicates the position on the display unit of the display device, and the vertical axis indicates the luminance value in the front direction.
[0012]
As shown in FIG. 44, the light leakage in the front direction of the dark display portion has a luminance value of 24-28 cd / m. ² The light leakage in the front direction of the bright display part is a luminance value of 4 to 5 cd / m. ² Met. Therefore, the light leakage in the front direction was about 7 times larger in the dark display portion than in the bright display portion. Further, the light leakage in the dark display portion was uneven with respect to the position, and uneven color was also observed. In addition, luminance value 4-5cd / m ² Is a value that is sufficiently visible in a dim environment. In addition, when observed from an oblique direction, depending on the direction, 4 to 5 cd / m from the bright display portion. ² The above light leakage was observed. As described above, when the shutter closed state of the conventional display device is caused to function as a mirror, the contrast ratio of the reflected image is significantly reduced due to light leakage. For this reason, it is not enough as a mirror to reflect the face and figure of a person.
[0013]
As the reflective polarizing plate, for example, a birefringent reflective polarizing film in which a plurality of different birefringent polymer films disclosed in International Publication No. WO95 / 27919 of the international application are alternately laminated can be used. . Such a reflective polarizing plate is usually disposed between a polarizing plate disposed on the back side of a liquid crystal element and an illumination device (backlight), and used for the purpose of improving the utilization efficiency of illumination light. An extremely high effect can be obtained. However, when realizing the mirror performance as intended by the present invention, the leakage of light with respect to a predetermined polarization becomes a big problem, so that sufficient mirror performance cannot be obtained only with such a reflective polarizing plate.
[0014]
An object of the present invention is to provide an apparatus capable of switching between a state in which a high-quality image is displayed and a mirror state in which an easy-to-see reflected image suitable for a person to view his / her face and figure is obtained. And
[0015]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention, an apparatus capable of switching between an image display state and a mirror state having the following configuration is provided.
[0016]
That is, an image display unit that emits image light for displaying a desired image, an image transmission state that transmits the image light, and a mirror state that reflects external light, which are arranged to overlap the image display unit A mirror function unit that can be switched to
The mirror function unit includes a reflection type polarization selection unit, a transmission polarization axis variable unit, and an absorption type polarization selection unit, which are sequentially arranged from the image display unit side, and the reflection type polarization selection unit is predetermined. The first polarized light having the polarization axis is transmitted, the second polarized light whose polarization axis intersects with the first polarized light is reflected, and the transmitted polarization axis varying means converts the incident first polarized light to the second polarized light. Can be switched between a state in which the polarized light is transmitted and a state in which it is transmitted without changing the polarization axis of the incident light, and the absorptive polarization selection means is capable of switching between the first polarized light and the second polarized light. One penetrates and the other absorbs,
The image display unit includes an image light polarization selection unit that transmits the first polarization and absorbs the second polarization, and the image display unit transmits the first polarization transmitted through the image light polarization selection unit. It is an apparatus capable of switching between an image display state and a mirror state characterized by being emitted as light.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
In this embodiment, a device capable of switching between an image display state and a mirror state (that is, a display device with a mirror function or a mirror with a display function) is provided. In the mirror state, this device can prevent light leakage of image display light and obtain a bright reflection image with a high contrast ratio. Therefore, the apparatus of this embodiment is suitable for a person to project and observe his / her face and figure in the mirror state. In general, it is considered that how a person's face looks depends on physical quantities such as the size of the part, the luminance value, and the contrast ratio (luminance contrast), and the greater the contrast ratio (luminance contrast), the easier it is to see. High evaluations have been confirmed by evaluation experiments (Shino Okuda, Ryuji Sato: Fundamental study on construction of evaluation method for human face appearance, Journal of Lighting Society, Vol. 84, No. 11, pp809-814) . In addition, in the image display state, the apparatus according to the present embodiment can obtain a bright image with little deterioration in image quality such as reflection of external light and a decrease in contrast ratio even in a bright environment.
[0018]
Hereinafter, a display device with a function of switching to a mirror state according to an embodiment of the present invention will be described with reference to FIGS.
[0019]
First, the basic configuration and operation of the display device with a function of switching to the mirror state according to the first embodiment will be described with reference to FIGS.
[0020]
As shown in FIG. 1, the display device according to the first embodiment includes an image display unit 1000, a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and an absorption polarization selection member 500 arranged in order. And have. The image display unit 1000 includes an absorptive polarization selection member 208 that transmits a linearly polarized light component in a predetermined direction and absorbs a linearly polarized component in a direction orthogonal thereto, and the absorptive polarization selection member 208 includes a reflective polarized light. It is arranged on the selection member 300 side. In the present embodiment, image display unit 1000 includes an illumination device, a liquid crystal layer, and two absorption polarization selection members that sandwich the liquid crystal layer. Of the two absorptive polarization selection members, the one on the output side is an absorptive polarization selection member 208. The voltage applied to the liquid crystal layer is changed between the bright display area and the dark display area, and linearly polarized light that passes through the absorption-type polarization selection member 208 is emitted from the bright display area, and the absorption-type polarization selection member 208 is emitted from the dark display area. The light is absorbed and not emitted. Thus, the image is displayed. Therefore, the image light (bright display light) emitted from the image display unit 1000 is linearly polarized light having a polarization axis that matches the transmission polarization axis of the absorption-type polarization selection member 208. Hereinafter, linearly polarized light having a polarization axis in the same direction as the polarization axis of the image light is referred to as “first linearly polarized light”. The linearly polarized light in the direction in which the first linearly polarized light and the polarization axis are orthogonal to each other is referred to as “second linearly polarized light”.
[0021]
The reflective polarization selection member 300 is a member that transmits a linearly polarized light component in a predetermined direction and reflects a linearly polarized light component orthogonal thereto. Here, the reflection type polarization selection member 300 is arranged in such a direction as to transmit the first linearly polarized light component and reflect the second linearly polarized light component.
[0022]
The transmission polarization axis variable unit 400 is an element having a structure in which a state where the polarization axis is changed when incident linearly polarized light is transmitted and a state where the polarization axis is not changed can be selected by electrical switching. In this embodiment, a liquid crystal element including a liquid crystal layer 407 and transparent electrodes 403 and 406 for applying a voltage to the liquid crystal layer 407 is used as the transmission polarization axis variable unit 400. The transparent electrode 403 is connected to a changeover switch 813 for switching on / off the voltage. When the voltage applied to the liquid crystal layer 407 is turned off by the changeover switch 813, the liquid crystal layer 407 is in a state in which the polarization axis of the incident linearly polarized light is changed, and when the voltage is turned on, the polarization axis is not changed. Become. In this embodiment mode, the liquid crystal layer 407 is a so-called twisted structure in which the major axis of the liquid crystal molecules 407a is continuously twisted by 90 ° between the transparent electrode 403 and the transparent electrode 406 when the voltage is off. This is a nematic (TN) type liquid crystal. The alignment direction of the liquid crystal layer 407 is determined to be a direction in which the first linearly polarized light incident from the reflective polarization selection member 300 side is changed to the second linearly polarized light. On the other hand, when the voltage is on, the liquid crystal molecules 407a of the liquid crystal layer 407 are in a state of standing perpendicular to the transparent electrodes 403 and 406 as shown in FIG. 2, and the polarization axis of the incident light is not changed.
[0023]
The absorption polarization selection member 500 is a member that transmits a linearly polarized light component in a predetermined direction and absorbs a linearly polarized light component in a direction orthogonal thereto. Here, the absorptive polarization selection member 500 is arranged so as to absorb the first linearly polarized light component and transmit the second linearly polarized light component of the incident light.
[0024]
Note that the observer observes the display device from the absorption polarization selection member 500 side (the left side in FIG. 1).
[0025]
Next, the operation of the display device according to the first embodiment will be described with reference to FIGS.
[0026]
When the display device of this embodiment is used in an image display state, the changeover switch 813 is turned off and the liquid crystal molecules 407a of the liquid crystal layer 407 of the transmission polarization axis variable unit 400 are twisted by 90 ° as shown in FIG. Set to the status. In this state, desired image light (bright display light) 3001 is emitted from the image display unit 1000. Since the image light 3001 is light that has passed through the absorption-type polarization selection member 208 of the image display unit 1000, it is first linearly polarized light. Therefore, the polarization axis of the image light 3001 coincides with the transmission polarization axis of the reflective polarization selection member 300, passes through the reflection polarization selection member 300, and enters the transmission polarization axis variable unit 400. As described above, since the liquid crystal layer 407 of the transmission polarization axis variable unit 400 is set in the OFF state, the incident linearly polarized image light 3001 has a polarization axis along the twist of the liquid crystal molecules 407a. It is rotated and emitted as second linearly polarized light. Since the polarization axis of the image light 3001 that has become the second linearly polarized light coincides with the transmission polarization axis of the absorptive polarization selection member 500, the image light 3001 is transmitted through the image light 3001 and observed by the observer.
[0027]
On the other hand, the external light 3002 incident on the display device from the observer side in the image display state is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed, and the second Only the linearly polarized light component is transmitted. The second linearly polarized external light 3002 that has passed through the absorption polarization selection member 500 changes from the second linearly polarized light to the first linearly polarized light when passing through the transmission polarization axis variable unit 400. Accordingly, since the polarization axis coincides with the transmission polarization axis of the reflective polarization selection member 300, the light is transmitted without entering the image display unit 1000 without being reflected by the reflective polarization selection member. The incident external light 3002 of the first linearly polarized light has its polarization axis coincident with the transmission polarization axis of the absorption-type polarization selection member 208, and therefore transmits through the absorption-type polarization selection member 208 and the liquid crystal layer of the image display unit 1000. Is incident on. At this time, the light incident on the dark display region is absorbed by the absorptive polarization selection member disposed closer to the illumination device than the liquid crystal layer. Therefore, it does not return to the observer side. In addition, the light incident on the bright display region is transmitted through the absorption type polarization selection member on the light source side and reaches the illumination device. A part of the light that reaches the lighting device is reflected by this, but the reflected light is substantially the same as the illumination light and becomes a part of the illumination light. Must not. That is, in the display device of this embodiment, even when external light is incident in the image display state, there is almost no reflection of external light that degrades the image quality.
[0028]
As described above, the display device according to the present embodiment provides a bright image in the image display state because the image light 3001 travels to the observer with almost no loss. On the other hand, since the external light 3002 is hardly reflected by the display device, there is almost no deterioration in image quality due to reflection of external light such as reflection and a decrease in contrast ratio.
[0029]
Next, a case where the display device of this embodiment is used by switching to the mirror state will be described. In this case, as shown in FIG. 2, the changeover switch 813 is turned on to set the liquid crystal molecules 407a of the liquid crystal layer 407 of the transmission polarization axis variable unit 400 to stand.
[0030]
At this time, the external light 3002 from the observer side toward the display device is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed and only the second linearly polarized light component is present. Is transmitted and enters the transmission polarization axis variable unit 400. Since the transmission polarization axis variable unit 400 is in a state in which the liquid crystal molecules 407a of the liquid crystal layer 407 are standing, the incident external light 3002 passes through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization state. The light passes through and reaches the reflective polarization selection member 300. Since the reflection polarization axis of the reflection type polarization selection member 300 coincides with the polarization axis of the second linear polarization, the external light 3002 is reflected by the reflection type polarization selection member 300. The external light 3002 reflected by the reflective polarization selection member 300 enters the transmission polarization axis variable unit 400 again, is transmitted through the second linearly polarized light as it is, and is further transmitted by the absorption polarization selection member 400. And head to the observer. Thereby, a reflection image of the external light 3002 is obtained and a mirror state is realized.
[0031]
In this mirror state, the image light (bright display light) 3001 emitted from the image display unit 1000 is the first linearly polarized light that has passed through the absorption-type polarization selection member 208. The light passes through and enters the transmission polarization axis variable unit 400. Since the transmission polarization axis variable unit 400 is in the on state, the polarization state of the image light 3001 is transmitted without changing, and enters the absorption polarization selection member 500 without changing the first linear polarization. Since the first linearly polarized light coincides with the absorption polarization axis of the absorption-type polarization selection member 500, it is absorbed by the absorption-type polarization selection member 500 and is not observed by the observer.
[0032]
That is, in the mirror state, the light from the image display member does not reach the observer, while the external light 3002 incident on the display device from the surroundings is ideally half of the unpolarized light. Since it reflects by the selection member 300 and goes to the observer side, it functions as a bright mirror.
[0033]
In the case of the mirror state, the display device of this embodiment can significantly reduce light leakage as compared with the display device of the republication publication of International Publication No. WO99 / 04315. In International Publication No. WO99 / 04315, in the mirror state, light leakage from the dark display portion due to the reflection performance of the reflective polarizing plate was a problem. However, in the display device of this embodiment, the image display portion 1000 absorbs the light. Since the polarization type selection member 208 is provided and the illumination light in the dark display area is absorbed, the light does not reach the reflection type polarization selection member 300 in the dark display area. For this reason, light leakage from the dark display region is hardly observed regardless of the performance of the reflective polarization selection member 300.
[0034]
In addition, the display device of this embodiment has a configuration in which the transmission polarization axis variable unit 400 is turned on and the liquid crystal molecules 407a are raised in the mirror state. In general, in a nematic liquid crystal, the deviation of the polarization axis of light emitted in an oblique direction is smaller when the voltage-on liquid crystal molecules are erected than when the voltage-off liquid crystal molecules are twisted. For this reason, the display device of this embodiment is in the oblique direction of the image light (bright display light) 3001 in the mirror state, as compared with the configuration in which the voltage is turned off in the mirror state described in the prior art. The effect that there is little light leakage of is also acquired.
[0035]
The leakage of light from the image display unit 1000 in the mirror state will be specifically described with reference to the graphs of FIGS. FIG. 3 shows the magnitude of light leakage in the bright display area and FIG. 4 shows the brightness value in the dark display area. These graphs show a luminance of 450 cd / m when the display device is in the image display state. ² The horizontal axis indicates the position on the display unit of the display device, and the vertical axis indicates the luminance value in the front direction, that is, in the direction perpendicular to the screen. 3 and 4, the light leakage of each of the configurations using the A-type polarizing plate, the B-type polarizing plate, and the C-type polarizing plate as the absorption-type polarization selection member 208 of the image display unit 1000, and the image display unit The absorption-type polarization selection member 208 is removed from 1000, and other configurations show light leakage of an apparatus similar to the display apparatus of the present embodiment. Even when the absorption polarization selection member 208 was removed, a normal level image could be displayed in the image display state. Details of the A, B, and C type polarizing plates will be described later.
[0036]
As shown in FIG. 3, in the bright display region in the mirror state, the display device of the present embodiment using the absorption-type polarization selection member 208 has half light leakage than the device without the absorption-type polarization selection member 208. To a certain extent. For this reason, the display device of the present embodiment can realize a mirror that displays a reflected image with a high contrast ratio. Further, in the dark display region portion in the mirror state, as shown in FIG. 4, the display device of the present embodiment using the absorption-type polarization selection member 208 has almost no leakage of light, and thus has a higher contrast ratio and is easy to see. A mirror that reflects the reflected image can be realized. On the other hand, in a display device that does not use the absorption polarization selection member 208, a large amount of light leakage occurs in the dark display region as shown in FIG.
[0037]
From these facts, it is shown that the display device of the present embodiment can realize a highly visible mirror by making the display of the image display unit 1000 dark display when in the mirror state. This is because the display device configured without the absorption-type polarization selection member (polarizing plate) 208 shown in FIGS. 3 and 4 and the conventional display device shown in FIG. This contrasts with the fact that light leaks more than the bright display area.
[0038]
Therefore, in this embodiment, when the entire screen is in a mirror state, the entire image display unit 1000 is darkly displayed or the illumination device itself of the image display unit 1000 is in a non-light emitting state. Further, when only a partial region of the transmission polarization axis variable unit 400 is in the voltage-on state and only a part of the screen is in the mirror state, the image display unit 1000 in the region overlapping the region to be in the mirror state is displayed darkly or Non-light emitting state. As a result, light leakage from the mirror state can be reduced, and a reflected image with a high contrast ratio can be displayed.
[0039]
Specifically, in order to switch to the mirror state, if the changeover switch 813 is turned on, a circuit that darkens the liquid crystal element of the image display unit 1000 is provided in conjunction with the changeover switch 813 or the image is displayed. A circuit for turning off the lighting device behind the liquid crystal element of the display portion 1000 can be provided. When the illumination device is turned off in the mirror state, the power consumption of the display device can be reduced. When only a part of the screen is in the mirror state and the image is displayed in the remaining part, the display of the image display area becomes dark when the illumination device on the back of the liquid crystal element is turned off. It is desirable that the image display unit 1000 in the overlapping area is darkly displayed. As a result, it is possible to simultaneously realize a mirror state that realizes a reflected image with a high contrast ratio and a bright image display on the same screen.
[0040]
As the image display unit 1000, a self-luminous display unit such as an organic electroluminescence (EL) element can be used in addition to a liquid crystal element. An absorption polarization selection member 208 is provided at a position facing the reflective polarization selection member 300 of the EL element. In the case of using an EL element, light leakage can be eliminated in principle by stopping the light emission itself of the EL element in a dark display state in conjunction with switching to the mirror state. As a result, it is possible to realize a high-quality mirror state in which a reflected image with a high contrast ratio can be obtained, and to reduce the power consumption of the display device.
[0041]
Further, by using a discharge lamp such as a metal halide lamp as a light source of the illumination device of the image display unit 1000 and combining it with a liquid crystal element, the display device of this embodiment can be a projection display device. In this case, since the discharge lamp cannot be turned on and off quickly, it is possible to reduce light leakage by making the display of the image display unit 1000 dark display in conjunction with switching to the mirror state. desirable.
[0042]
In the first embodiment, as shown in FIGS. 1 and 2, as the absorption-type polarization selection member 500, the transmission polarization axis is parallel to the polarization axis of the first linear polarization, and the absorption polarization axis is the second. Although the linearly polarized light parallel to the polarization axis is used, the present invention is not limited to this. The transmission polarization axis is parallel to the polarization axis of the second linearly polarized light, and the absorption polarization axis is the first. Those parallel to the polarization axis of linearly polarized light can be used. In this case, the display device is switched to the image transmission state by switching the transmission polarization axis variable unit 400 to the transmission state (voltage on state) without changing the incident polarization axis, and the transmission polarization axis variable unit 400 is changed to the first state. The display device is switched to the mirror state by switching to the state in which the polarized light is changed to the second polarized light (voltage off state).
[0043]
Next, a basic configuration and operation of the display device with a function of switching to the mirror state according to the second embodiment of the present invention will be described with reference to FIGS.
[0044]
In the display device of the second embodiment, the absorption-type polarization selection member 500 of the display device of FIGS. 1 and 2 of the first embodiment is combined with a reflection-type polarization selection member 301 and a variable polarization selection member 600. It has been replaced with. Since other configurations are the same as those of the display device of the first embodiment, the same parts are denoted by the same reference numerals and detailed description thereof is omitted.
[0045]
The reflective polarization selection member 301 is disposed at a position facing the transmission polarization axis variable unit 400, and the variable polarization selection member 600 is disposed closer to the viewer than the reflective polarization selection member 301. The reflective polarization selection member 301 is configured to reflect the first linearly polarized component and transmit the second linearly polarized component. The variable polarization selection member 600 can select either a state in which the first linearly polarized light component is absorbed and the second linearly polarized light component is transmitted in the incident light, or a state in which all the polarized light components are transmitted. It is.
[0046]
The display device according to the second embodiment is configured to be able to switch between the image display state and the mirror state by controlling the polarization state by the transmission polarization axis variable unit 400 and by controlling the absorption or transmission of polarized light by the variable polarization selection member 600. It is what. The observer observes the display device from the variable polarization selection member 600 side.
[0047]
Here, the variable polarization selection member 600 includes a guest-host type liquid crystal layer 607, transparent electrodes 603 and 606 for applying a voltage to the liquid layer 607, and a changeover switch 600a. When the changeover switch 600a is off, the liquid crystal layer 607 is oriented so that the major axis of the liquid crystal molecules 607a of the liquid crystal layer 607 is parallel to the first linearly polarized light as shown in FIG. Thereby, in the OFF state, the variable polarization selection member 600 absorbs the first linearly polarized light component and transmits the second linearly polarized light component whose polarization axis is orthogonal to the first linearly polarized light component. When the changeover switch 600a is on, the liquid crystal molecules 607a are perpendicular to the transparent electrodes 603 and 606 as shown in FIG. 6, so that the variable polarization selection member 600 transmits all polarization components.
[0048]
The operation when the display device of the second embodiment is in the image display state will be described with reference to FIG. In the case of the image display state, the changeover switch 813 is turned off to turn off the transmission polarization axis variable unit 400, and in conjunction with this, the changeover switch 600a is also turned off to turn off the variable polarization selection member 600.
[0049]
The image light 3001 emitted from the image display unit 1000 passes through the reflective polarization selection member 300 and enters the transmission polarization axis variable unit 400. At this time, since the transmission polarization axis variable unit 400 is in the OFF state, the passing image light 3001 changes from the first linearly polarized light to the second linearly polarized light. Since the image light 3001 transmitted through the transmission polarization axis variable unit 400 is the second linearly polarized light, the polarization axis coincides with the transmission polarization axis of the reflective polarization selection member 301 and is transmitted therethrough. Furthermore, since it is also coincident with the transmission polarization axis of the variable polarization selection member 600 in the off state, this is also transmitted and observed by the observer.
[0050]
On the other hand, the external light 3002 incident on the display device in the image display state from the viewer side is non-polarized light, but the variable polarization selection member 600 is in the off state, and therefore the first light beam coincides with the absorption polarization axis of the variable polarization selection member. The first linearly polarized light component is absorbed, and only the second linearly polarized light component that coincides with the transmission polarization axis is transmitted. The second linearly polarized external light 3002 that has passed through the variable polarization selection member 600 passes through the reflective polarization selection member 301 and passes through the transmission polarization axis variable unit 400, and the first linearly polarized light is transmitted from the second linearly polarized light to the first light. The light changes into linearly polarized light, passes through the first reflective polarization selection member 300, and enters the liquid crystal layer of the image display unit 1000. At this time, as described in the first embodiment, the light that has entered the dark display region is absorbed by the absorption-type polarization selection member that is disposed closer to the illumination device than the liquid crystal layer. Therefore, it does not return to the observer side. In addition, the light that has entered the bright display area also passes through the absorption-type polarization selection member on the light source side and reaches the illumination device, and a part of the light is reflected, but the reflected light is substantially the same as the illumination light, Part of the illumination light. That is, in the display device of this embodiment, even when external light is incident in the image display state, there is almost no reflection of external light that degrades the image quality.
[0051]
Therefore, in the image display state, the image light 3001 travels to the observer with almost no loss, so that a bright image can be obtained. In addition, since the external light 3002 is hardly reflected by the display device, image quality deterioration such as reflection of external light and a decrease in contrast ratio does not occur.
[0052]
Next, when the display device of the second embodiment is in a mirror state, the operation will be described with reference to FIG. In the mirror state, the changeover switch 813 and the changeover switch 600a are turned on in conjunction with each other, and the transmission polarization axis variable unit 400 and the variable polarization selection member 600 are turned on.
[0053]
In the mirror state, all the polarization components of the external light 3002 incident on the display device from the viewer side are transmitted through the variable polarization selection member 600 as shown in FIG. The external light 3002 that has passed through the variable polarization selection member 600 enters the reflective polarization selection member 301. Of the external light 3002 incident on the reflection type polarization selection member 301, the second linear polarization component is transmitted through the reflection type polarization selection member 301, the first linear polarization component is reflected by the reflection type polarization selection member 301, and again. The light passes through the variable polarization selection member 600 and travels toward the viewer. On the other hand, the second linearly polarized light component transmitted through the reflective polarization selection member 301 is transmitted through the transmission polarization axis variable unit 400 without changing the polarization axis, reflected by the reflective polarization selection member 300, and again transmitted through the transmission polarization axis. The light passes through the variable unit 400, the reflective polarization selection member 301, and the variable polarization selection member 600 and travels toward the viewer.
[0054]
As described above, in the display device according to the second embodiment, most of the incident external light 3002 is reflected by the reflective polarization selection member 300 and the reflective polarization selection member 301. Therefore, a mirror state in which an extremely bright reflected image is obtained can be obtained.
[0055]
On the other hand, in the mirror state, the image light (bright display light) 3001 emitted from the image display unit 1000 passes through the absorption polarization selection member 208 as described in the first embodiment. The first linearly polarized light. Therefore, after the image light 3001 is transmitted through the reflective polarization selection member 300, the image light 3001 is transmitted through the transmission polarization axis variable unit 400 as the first linearly polarized light without changing the polarization axis, and reflected by the reflective polarization selection member 301. Then, since it returns to the image display part 1000, it is hardly observed by an observer.
[0056]
In order to further reduce light leakage from the image display unit 1000 side in the mirror state, as described in the first embodiment, the image display unit 1000 corresponding to the region in the mirror state is used. It is desirable to make the display area dark. When the entire display area is a mirror area, light leakage can be eliminated by setting the illumination device of the image display unit to a non-light emitting state.
[0057]
As described above, in the display device according to the second embodiment, since most of the polarization component of the external light 3002 is reflected in the mirror state, an extremely bright reflected image is obtained and light leakage of the image light 3001 is small. An easy-to-see mirror is obtained. In the image display state, as in the first embodiment, a bright image can be displayed with little reflection of external light.
[0058]
In the second embodiment, as the second reflection type polarization selection member 301, the reflection polarization axis is parallel to the polarization axis of the first linear polarization as shown in FIGS. Although the one parallel to the polarization axis of the second linearly polarized light is used, the present invention is not limited to this configuration. The reflection polarization axis is parallel to the polarization axis of the second linearly polarized light and the transmission polarization axis is Those parallel to the polarization axis of the first linearly polarized light can be used. In this case, the transmission polarization axis variable unit 400 is switched to a transmission state (voltage on state) without changing the incident polarization axis, and the variable polarization selection unit 600 absorbs the second linearly polarized light and absorbs the first straight line. By switching to a state in which polarized light is transmitted (voltage off state), the display device is switched to an image transmission state, and the transmission polarization axis variable unit 400 is in a state in which the first linearly polarized light is changed to the second linearly polarized light (voltage off). The display device can be switched to the mirror state by switching the variable polarization selection unit 600 to a state that transmits all polarization components (voltage on state).
[0059]
In the first and second embodiments described above, when a liquid crystal element is used as the image display unit 1000, a transmissive liquid crystal element including an illumination device has been described. However, a reflective liquid crystal element may be used. Is possible.
[0060]
Further, when the polarization degree of the absorption polarization selection member 208 constituting the image display member is P1, and the polarization degree of the absorption polarization selection member 500 is P2, the relationship of 0.966 ≦ P1 ≦ 0.995 ≦ P2 is satisfied. Or 0.966 ≦ P2 ≦ 0.995 ≦ P1 is preferably satisfied. The reason for this will be described in Example 2 described later.
[0061]
In the display devices of the first and second embodiments, it is preferable to form an antireflection film on the surfaces of the absorption polarization selection members 500 and 208 and the outermost surface of the variable polarization selection member 600.
[0062]
In the present invention, the distance between the reflective polarization selection member 300 and the reflective polarization selection member 301 is preferably 0.11 mm or less. The reason for this will be described in Example 2 described later.
[0063]
In the present invention, when the display device is in a mirror state, it is preferable that the entire region of at least 58.6 mm × 39.1 mm is substantially a mirror. This is a size determined in consideration of reflecting a quarter of the face of an adult male. This will also be described in an embodiment described later.
[0064]
In the first and second embodiments, a film-like member can be used as the reflective polarization selection members 300 and 301. In this case, the film-like member is directly adhered to a transparent substrate that is highly rigid, flat, transparent, and optically isotropic through a transparent adhesive, or indirectly through a flat film or the like. It is desirable to fix the adhesive surface so that there is no distortion.
[0065]
Moreover, the display device of the first and second embodiments can be a projection-type display device in which the projection light emitted from the projection device is applied to the transmission screen via the mirror member. In this case, the transmission screen may be provided with a mirror function unit. In this case, the projection device emits linearly polarized light in which the polarization states of the respective color lights coincide as projection light, and the linearly polarized light becomes s-polarized light or p-polarized light with respect to the reflection surface of the mirror member. Configure as follows.
[0066]
Furthermore, of the mirror function unit and the optical system constituting the transmission screen, the mirror function unit can be detachable so that the mirror function unit can be removed when the mirror function is unnecessary. Or it is good also as a structure which comprises the screen which does not contain an image display part and was provided with the mirror function part independently, and attaches this mirror function screen to arbitrary display apparatuses as needed.
[0067]
In the first and second embodiments, as the reflective polarization selection members 300 and 301, thousands of angstroms (10 ^-Ten The thing of the structure which has arrange | positioned a conductive metal linear pattern with the pitch of m) can be used. At this time, the longitudinal direction of the metal linear pattern becomes the reflection polarization axis. In addition, several thousand angstroms (10 ^-Ten A conductive metal linear pattern is formed at a pitch of m), and a part of adjacent linear patterns is electrically connected, and the transparent electrode and the reflective polarization selection member can be used together. Thereby, the transparent electrode 606 and the reflective polarization selection member 301, or the reflective polarization selection member 301 and the transparent electrode 403, or the transparent electrode 406 and the reflective polarization selection member 300 can be configured.
[0068]
In the first and second embodiments, the image display member 1000 can have the following structure. That is, a pair of transparent substrates bonded with a certain gap, a liquid crystal layer sandwiched between the transparent substrates, and pixel electrodes arranged in a matrix formed by transparent electrodes on at least one of the pair of transparent substrates A liquid crystal element including a group, an absorption-type polarization selection member 208 disposed on the viewer side, and an absorption-type polarization selection member disposed on the transparent substrate on the opposite side of the viewer side, an image signal on the pixel electrode group The display liquid crystal element driving unit for applying a voltage corresponding to the above, and a lighting device disposed on the back surface of the display liquid crystal element. At this time, the lighting device can be configured to include a switching unit that switches between lighting and extinguishing in conjunction with the switch 813. The illumination device may include a light source that sequentially emits a plurality of color lights, and the liquid crystal element may be configured to perform field sequential color display corresponding to the color light from the illumination device.
[0069]
Further, the image display unit 1000 may be configured to use a reflective liquid crystal element. In this case, as the reflective liquid crystal element, a transparent substrate and a reflective substrate having a reflective portion are bonded together via a spacer such as a bead, the periphery is sealed with a frame-shaped sealing material, and the gap between the two substrates is A liquid crystal sealed and sealed can be used. At this time, a phase difference plate is laminated on the transparent substrate. Note that a color filter can be provided on the transparent substrate or the reflective substrate. This color filter preferably has a function of increasing darkness in dark display, and more specifically, it is more desirable to use a color filter of a delta arrangement.
[0070]
Further, the display devices of the first and second embodiments can be configured such that the size of the region in the mirror state and the size of the image display region in the image display state are different. Further, as the image display unit 1000, a display liquid crystal element that functions as a transmission type in some display areas and functions as a reflection type in other areas, and an illumination device for illuminating the area functioning as the transmission type The thing of the structure provided with these can be used.
[0071]
In the display device of the first and second embodiments, the display area of the image display unit may be divided into a plurality of areas, and switching control between the mirror state and the image display state is performed for each divided area. good. In order to realize this, the light transmission surface of the transmission polarization axis variable unit 400 and the variable polarization selection member 600 is divided into a plurality of regions, and the state in which the polarization axis of the light that is transmitted for each individual region is changed and the state that does not change And selection control of polarized light to be absorbed.
[0072]
【Example】
Examples of the present invention will be described below.
[0073]
Example 1
A display device with a function of switching to the mirror state according to the first embodiment of the present invention will be described with reference to FIGS. The display device of Example 1 has the same basic configuration as the display device shown in FIGS. 1 and 2 of the first embodiment.
[0074]
As in the first embodiment, the display device of FIG. 7 of Example 1 includes an image display unit 1000, a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and an absorption type, which are sequentially stacked. And a polarization selection member 500. These are housed in a housing 1070 having an opening 1071. The opening 1071 serves as an image display unit that can be switched to a mirror state. The operation of each part is as described in the first embodiment.
[0075]
As shown in FIGS. 7 and 8, the image display unit 1000 includes a display liquid crystal element, and a liquid crystal display panel 200 that displays an image by adjusting the amount of transmitted light, and an illumination device disposed on the back surface thereof. 100. As the liquid crystal display panel 200, a liquid crystal display panel using a display mode such as a TN (Twisted Nematic) mode, an STN (Super Twisted Nematic) mode, or an ECB (Electrically Controlled Birefringence) mode is preferably used. Since such a liquid crystal display panel performs display by modulating the polarization state of light incident on the liquid crystal layer using a polarizing plate, a high contrast ratio can be obtained with a relatively low driving voltage. Further, linearly polarized light is emitted as image light by the polarizing plate functioning as the absorption polarization selection member 208 disposed on the reflective polarization selection member 300 side of the liquid crystal display panel 200.
[0076]
As is generally known, the liquid crystal display panel 200 includes two types of liquid crystal display panels based on active matrix driving using switching elements such as TFTs (Thin Film Transistors) and multiplex driving liquid crystal display panels. There is a method, and either can be selected and used. Specifically, a liquid crystal display panel driven by an active matrix such as a TN (Twisted Nematic) liquid crystal display panel, an IPS (In Plane Switching) liquid crystal display panel, an MVA (Multi-domain Vertical Aligned) liquid crystal display panel, or an STN (Super Twisted) A multiplex drive liquid crystal display panel such as a Nematic liquid crystal display panel can be used. In the first embodiment, a case where a TN liquid crystal display panel is used as the liquid crystal display panel 200 will be described, but the present invention is not limited to this.
[0077]
A detailed configuration of each part of the display device according to the first embodiment will be described with reference to FIG.
[0078]
As the illumination device 100, a device that can uniformly illuminate the image display unit of the liquid crystal display panel 200 is used. As an illumination device, an edge light method (light guide method), a direct method (reflecting plate method), a planar light source method, etc. (Liquid Crystal Display Technology, p252-256, Sangyo Tosho Co., Ltd., issued on November 8, 1996) : Full color liquid crystal display technology, p201-202, triceps, Inc., issue date February 26, 1990) is generally known. As the lighting device 100, an optimum method may be selected from these methods and other methods according to the purpose, purpose, and screen size. Here, the case where an edge light system is used as the illumination device 100 will be described, but the present invention is not limited to this.
[0079]
The illuminating device 100 includes a light guide body 103 made of a transparent acrylic resin that has been subjected to processing such as dot printing 105 with a white pigment on the back surface, and a linear light source 101 made of, for example, a cold cathode tube disposed on an end surface of the light guide body 103. And a lamp cover 102, a reflection sheet 104 disposed on the back surface of the light guide 103, diffusion sheets 110 and 112 disposed on the front surface of the light guide 103, and a prism sheet 111.
[0080]
In this configuration, light emitted from the light source 101 enters the light guide 103 directly or after being reflected by the lamp cover 102. The light 1101 incident on the light guide body 103 propagates through the light guide body 103 while being totally reflected, but the light that has reached the dot print 105 with the white pigment applied to the back surface of the light guide body 103 has a traveling direction thereof. Instead, the light is emitted from the surface of the light guide 103. The light emitted from the light guide 103 is emitted to the liquid crystal display panel 200 after the emission angle distribution and the in-plane luminance distribution are uniformized by the diffusion sheets 110 and 112, the prism sheet 111, and the like.
[0081]
As shown in FIG. 8, the liquid crystal display panel 200 includes a first transparent substrate 201 and a second transparent substrate 202 made of flat, transparent, and optically isotropic glass or plastic. On the transparent substrate 201, a color filter (not shown), a transparent electrode 203 made of ITO (Indium Tin Oxide), and an alignment film 204 made of polyimide polymer are laminated. On the second transparent substrate 202, an alignment film 206, a transparent electrode 205 that forms a pixel, and a switching element (not shown) such as an electrode or a thin film transistor connected thereto are formed. The two transparent substrates 201 and 202 face each other on the surface on which the alignment films 204 and 206 are formed, and a certain gap is provided between the two transparent substrates 201 and 202 via a spacer (not shown). Further, the periphery is sealed with a frame-shaped sealing material 210 to form a space inside. A liquid crystal layer 207 is provided by sealing nematic liquid crystal having positive dielectric anisotropy in this space.
[0082]
The major axis alignment direction of the liquid crystal molecules of the liquid crystal layer 207 is defined by performing an alignment process such as rubbing on the alignment films 204 and 206 formed on the two transparent substrates 201 and 202. Here, the transparent substrates 201 and 202 are continuously twisted by 90 °. On the back surface of the transparent substrate 202 and on the front surface of the transparent substrate 201, a polarizing plate 209 and an absorption-type polarization selection member (polarizing plate) 208 are disposed so as to transmit linearly polarized light whose polarization axes are orthogonal to each other. The orientation directions of the major axes of the liquid crystal molecules on the transparent substrate 202 side and the transparent substrate 201 side are both parallel or orthogonal to the transmission polarization axes of the polarizing plate 209 and the absorption-type polarization selection member (polarizing plate) 208. It is configured.
[0083]
As the absorption type polarization selection member (polarizing plate) 208 and the polarizing plate 209, for example, a film obtained by applying a protective function layer of triacetyl cellulose on both surfaces of a film imparted with a polarizing function by absorbing iodine into stretched polyvinyl alcohol. Can be used. Note that the absorptive polarization selection member (polarizing plate) 208 and the polarizing plate 209 are bonded to the transparent substrate 202 and the transparent substrate 201, respectively, so as to be optically bonded with an acrylic adhesive.
[0084]
With such a configuration, the linearly polarized light that has passed through the polarizing plate 209 out of the illumination light incident from the back surface (illuminating device 100 side) of the liquid crystal display panel 200 passes through the liquid crystal layer 207 and is absorbed by the absorptive polarization selection member (polarized light). Plate) 208. At this time, the polarization state of light transmitted through the liquid crystal layer 207 can be changed by a voltage applied to the liquid crystal layer 207. Therefore, by applying a voltage corresponding to the image information transmitted from the image information generation unit (not shown) to the transparent electrodes 203 and 205 and applying an electric field to the liquid crystal layer 207, polarization of light passing through the liquid crystal layer 207 is achieved. The amount of light transmitted through the absorption type polarization selection member (polarizing plate) 208 can be controlled by changing the state. Thereby, desired image light composed of linearly polarized light can be formed.
[0085]
Next, the reflective polarization selection member 300 will be described.
[0086]
The reflective polarization selection member 300 uses a function of transmitting a first linearly polarized light component emitted from the image display unit 1000 and having a function of specularly reflecting a second linearly polarized light component having a polarization axis perpendicular thereto. . As such a member, for example, a birefringence reflective polarizing film in which a plurality of different birefringent polymer films disclosed in International Publication No. WO95 / 27919 is alternately laminated, or a cholesteric liquid crystal layer is used. The one where the quarter wavelength plate is arrange | positioned to the front and back of this can be used. In the case of a birefringent reflection type polarizing film, a film that transmits a predetermined linearly polarized light component and mirror-reflects a linearly polarized light component whose polarization axis is orthogonal to this is commercially available from 3M Company (USA) under the trade name DBEF. This can be used as the reflective polarization selection member 300. The reflective polarized light selection member 300 is an important member that functions as a mirror surface when the display device is in a mirror state. Therefore, the reflective polarized light selection member 300 is not subjected to a process for blurring the reflected image such as a mat process. use.
[0087]
On the other hand, in the case where the reflective polarization selection member 300 is configured by arranging a ¼ wavelength plate on the front and back of the cholesteric liquid crystal layer, the low-molecular cholesteric liquid crystal is accommodated between two alignment-treated transparent substrates. A liquid crystal cell or a polymer cholesteric liquid crystal layer formed on a flat, optically isotropic and transparent substrate such as glass or transparent resin can be used as the cholesteric liquid crystal layer. The cholesteric liquid crystal layer exhibits unique optical characteristics based on a helical molecular arrangement. Light incident in parallel to the helical axis reflects circularly polarized light in one rotational direction according to the rotational direction of the cholesteric helix, The other shows selective reflection of transmitting. Since the wavelength range of selective reflection is determined by the pitch of the molecular arrangement, it is necessary to stack and use a plurality of cholesteric liquid crystal layers having different pitches in order to cause selective reflection over the entire visible wavelength range. In this case, instead of stacking multiple cholesteric liquid crystal layers with different pitches, Asia Display 95 Digest, p735, The Institute of Television Engineers of Japan (ITE) & The Society for Information Display A cholesteric liquid crystal layer in which the pitch is continuously changed as described in (SID) may be used.
[0088]
In the case of using a reflection-type polarized light selection member 300 in which quarter-wave plates are arranged on the front and back of the cholesteric liquid crystal layer, a quarter-wave plate arranged on the back side of the cholesteric liquid crystal layer, that is, on the image display unit 1000 side Sets its slow axis in the following direction: That is, the slow axis is arranged so that the first linearly polarized light emitted from the image display unit 1000 and incident on the reflective polarization selection member 300 is converted into circularly polarized light that passes through the cholesteric liquid crystal layer. On the other hand, the quarter-wave plate similarly disposed on the front side of the cholesteric liquid crystal layer, that is, the transmission polarization axis variable unit 400 side, is arranged so that the circularly polarized light transmitted through the cholesteric liquid crystal layer is converted to the first linearly polarized light. Arrange the slow axis.
[0089]
In this way, when the second linearly polarized light is incident on the reflective polarization selection member having the structure in which the quarter wavelength plate is arranged on the front and back of the cholesteric liquid crystal layer, the second linearly polarized light is obtained from the quarter wavelength plate. By the action, it is converted into circularly polarized light opposite to the circularly polarized light transmitted through the cholesteric liquid crystal layer, so that it is selectively reflected by the cholesteric liquid crystal layer. The circularly polarized light reflected by the cholesteric liquid crystal layer is converted into the second linearly polarized light by its action when transmitted through the quarter-wave plate again.
[0090]
In addition, it is desirable to use the quarter wave plate used for the reflection type polarization selection member 300 having this configuration that functions as a quarter wave plate in the entire visible wavelength range. As the quarter-wave plate, a stretched polymer film having a high transmittance in the visible wavelength region, such as polyvinyl alcohol, polycarbonate, polysulfone, polystyrene, polyarylate, or the like can be used. In addition, a mica, a crystal, or a liquid crystal layer in which molecular axes are aligned in one direction can be used.
[0091]
In general, due to the wavelength dependence of the refractive index of the material constituting the quarter wavelength plate (hereinafter referred to as wavelength dispersion), one type of retardation plate functions as a quarter wavelength plate for the entire visible wavelength range. Although it is difficult to configure a plate, it is configured to function as a quarter-wave plate in a wide wavelength range by bonding at least two types of retardation plates with different wavelength dispersion so that their optical axes are orthogonal to each other. Use something.
[0092]
In addition, when using a film-like member, such as a birefringent reflection-type polarizing film or a laminated member of a film-like cholesteric liquid crystal layer and a quarter-wave plate, the following points should be noted. To do.
[0093]
That is, since the film-like reflective polarization selection member has low flatness as it is, it is difficult to realize a practically satisfactory mirror simply by placing it on the front surface of the image display unit 1000. Therefore, when a film-like member is used as the reflective polarization selection member 300, it is highly rigid, flat, transparent and optically isotropic, such as a glass plate or a plastic plate, through a transparent adhesive. It is desirable to adhere and fix to a transparent substrate so that there is no distortion.
[0094]
Alternatively, in order to fix the reflective polarization selection member 300 in a flat state, instead of adhesively fixing to a new transparent base material, the liquid crystal display panel 200 or a transparent polarization axis variable unit 400 described later is fixed to a transparent substrate. can do. In any case, when a film-like member is used as the reflective polarization selection member 300, it is desirable to adhesively fix it to another flat member in order to realize a mirror without distortion.
[0095]
Next, the transmission polarization axis variable unit 400 will be described.
[0096]
The transmission polarization axis variable unit 400 changes the polarization state when the incident linearly polarized light is transmitted, and changes the polarization state to the linearly polarized light whose polarization axis is orthogonal to the incident linearly polarized light. This is a configuration in which one of the states that are not changed can be selected. For example, a liquid crystal element as illustrated in FIG. 8 can be used.
[0097]
The transmission polarization axis variable part 400 includes a transparent electrode 403 made of ITO and a first transparent substrate 401 on which an alignment film 404 made of polyimide polymer is entirely laminated, a transparent electrode 406, and an alignment film. 405 includes a second transparent substrate 402 on which the entire surface is laminated, and a liquid crystal layer 407. The transparent electrodes 403 and 406 formed on the two transparent substrates 401 and 402 are connected to a power source via wiring (not shown) and a changeover switch 813 (see FIG. 1 and not shown in FIG. 8). . Therefore, either a state where no voltage is applied to the transparent electrodes 403 and 406 or a state where a voltage is applied can be selected. In other words, the transparent electrodes 403 and 406 have no potential difference and an electric field is not applied to the liquid crystal layer 407, and a voltage is applied to the transparent electrodes 403 and 406 and an electric field is applied to the liquid crystal layer 407. It is configured to be selectable.
[0098]
The liquid crystal layer 407 of the transmission polarization axis variable part 400 is arranged between two transparent substrates 401 and 402 by arranging two transparent substrates 401 and 402 so that the alignment film forming surfaces face each other and sandwiching a spacer (not shown). A space is formed by sealing a periphery of the space in a frame shape with a sealing material 410, and a nematic liquid crystal having positive dielectric anisotropy is sealed in the space.
[0099]
Here, as the transmission polarization axis variable section 400, alignment films 404 and 405 formed on the two transparent substrates 401 and 402 are each subjected to an alignment process such as a rubbing process, and two liquid crystal molecular major axes of the liquid crystal layer 407 are formed. A case of a so-called TN liquid crystal element configured to be continuously twisted by 90 ° between the transparent substrates 401 and 402 will be described.
[0100]
In this case, the alignment direction of the major axis of the liquid crystal molecules on the transparent substrate 402 side is configured to be parallel or orthogonal to the linearly polarized light transmission polarization axis of the absorption-type polarization selection member (polarizing plate) 208 of the liquid crystal display panel 200, and the liquid crystal layer Reference numeral 407 is configured to satisfy the conditions of the wave guide in the visible wavelength region. Wave guide conditions are described, for example, in a paper by CH Gooch and HA Tarry on pages 1575-1584 of J. Phys. D: Appl. Phys. Vol. 8 (1975).
[0101]
Here, when the birefringence of the liquid crystal is Δn and the thickness of the liquid crystal layer is d, d · Δn = 0.4552 (wavelength 633 nm).
[0102]
With the above configuration, the transmission polarization axis variable unit 400 of the present embodiment is in an off state where there is no potential difference between the transparent electrodes 403 and 406 formed on the two transparent substrates 401 and 402, respectively, and no electric field is applied to the liquid crystal layer 407. The first linearly polarized light emitted from the image display unit 1000 and transmitted through the reflective polarization selection member 300 is changed to second linearly polarized light having a polarization axis orthogonal thereto. On the other hand, when the voltage is applied to the transparent electrodes 403 and 406 formed on the two transparent substrates 401 and 402, respectively, and the electric field is applied to the liquid crystal layer 407, the light is emitted from the image display unit 1000 to select the reflection type polarization. The first linearly polarized light transmitted through the member 300 is transmitted without changing its polarization axis. At this time, if the voltage applied to the transparent electrodes 403 and 406 was ± 5 V and 60 Hz, it worked sufficiently.
[0103]
In the first embodiment, the transmission polarization axis variable unit 400 is a TN liquid crystal element. However, the present invention is not limited to this. That is, the transmission polarization axis variable unit 400 changes the polarization axis when the incident linearly polarized light is transmitted, and changes the polarization axis to a state in which the incident linearly polarized light is changed to linearly polarized light whose polarization axis is orthogonal. Any part can be selected as long as it is not allowed to be selected. In addition to the TN liquid crystal element, an ECB (Electrically Controlled Birefringence) liquid crystal element, a ferroelectric liquid crystal element, an antiferroelectric liquid crystal element, or the like can be used.
[0104]
Next, the absorption polarization selection member 500 will be described.
[0105]
The absorptive polarization selection member 500 absorbs the first linearly polarized light component of the incident light, and transmits the second linearly polarized light component whose polarization axis is orthogonal thereto, or transmits the first linearly polarized light component, The second linearly polarized light component has a function of absorbing, and a so-called polarizing plate can be used. That is, as the absorptive polarization selection member 500, for example, a polarizing plate in which a protective function layer of triacetyl cellulose is provided on both surfaces of a film obtained by absorbing iodine in stretched polyvinyl alcohol and imparting a polarization function can be used.
[0106]
Note that it is desirable that the absorption-type polarization selection member 500 be subjected to a process for suppressing regular reflection on the surface thereof in order to suppress deterioration of image quality due to reflection. However, what is important here is that the display device of the present invention also functions as a mirror. Therefore, as a treatment for preventing regular reflection of the absorption polarization selection member 500, fine irregularities are formed on the surface, or transparent fine particles are contained on the surface. A method of reducing the regular reflection component by forming a transparent resin layer is not desirable. This is because, when such processing is performed, the image display performance is improved by reducing the reflection, but the image reflected in the mirror is blurred and the mirror performance deteriorates.
[0107]
Therefore, it is desirable to form an antireflection film on the surface of the absorption-type polarized light selection member 500 for preventing regular reflection. A known technique can be used as the antireflection film. That is, a method in which several kinds of optically designed metal oxides having different refractive indexes are multilayer-coated by vapor deposition or a method in which a low refractive index material such as a fluorine compound is applied may be used.
[0108]
Next, the direction of the axis of each member of the display device of the present embodiment will be described with reference to FIG.
[0109]
Here, the absorptive polarization selection member 500 absorbs the first linearly polarized light component of the incident light and transmits the second linearly polarized light component whose polarization axis is orthogonal to the first linearly polarized light component. The angle of each axis is shown as an angle in the counterclockwise direction with reference to the position of the image display surface at 3 o'clock in the horizontal direction. As shown in FIG. 9, in the case where a TN liquid crystal display panel is used as the liquid crystal display panel 200 constituting the image display unit 1000, in order to obtain the horizontal symmetry of the viewing angle characteristic, the transmission of the linearly polarized light of the polarizing plate is usually performed. The polarization axis is 135 ° (or 45 °, 135 ° in this embodiment). Accordingly, the transmission polarization axis of the linearly polarized light of the reflective polarization selection member 300 is also 135 °, and the alignment directions of the liquid crystal molecular major axes on the transparent substrate 402 side and the transparent substrate 401 side of the transmission polarization axis variable unit 400 are 135 ° respectively. The transmission polarization axis of linearly polarized light of the absorption polarization selection member 500 is 45 ° and 45 °.
[0110]
Next, the operation of the display device according to the first embodiment will be described with reference to FIGS.
[0111]
A case where the display device of Example 1 is in an image display state will be described with reference to FIG. When the display device is in the image display state, the transmission polarization axis variable unit 400 turns off the changeover switch 813 so that a voltage is not applied to the liquid crystal layer 407 constituting the display device, that is, an off state. The linearly polarized light emitted from the illumination device 100 of the image display unit 1000 and transmitted through the absorption-type polarization selection member (polarizing plate) 208 of the liquid crystal display panel 200 is emitted from the image display unit 1000 as image light 3001. The image light 3001 composed of the first linearly polarized light is transmitted through the reflective polarization selection member 300 and enters the transmission polarization axis variable unit 400. The image light 3001 passing through the transmission polarization axis variable unit 400 changes from the first linearly polarized light to the second linearly polarized light. The second linearly polarized image light 3001 transmitted through the transmission polarization axis variable unit 400 is incident on the absorption polarization selection member 500. Since the absorption-type polarization selection member 500 absorbs the first linear polarization component and transmits the second linear polarization component, the second linear polarization image light 3001 passes through the absorption-type polarization selection member 500 for observation. Observed by the person.
[0112]
On the other hand, the external light 3002 incident on the display device from the observer side (left side in the figure) is non-polarized, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed and the second Only the linearly polarized light component is transmitted. When the external light 3002 that has passed through the absorptive polarization selection member 500 passes through the transmission polarization axis variable unit 400, the external light 3002 changes from the second linear polarization to the first linear polarization, and passes through the reflection polarization selection member 300 to form an image. Head to the display unit 1000. As described in the first embodiment, this light hardly returns to the observer side.
[0113]
Therefore, in the image display state, the image light 3001 emitted from the image display unit 1000 is directed to the observer with almost no loss, so that a bright image can be obtained. Further, since the external light 3002 is not reflected by the reflective polarization selection member 300 that functions as a mirror in the mirror state, the image quality is hardly deteriorated due to external light such as reflection and a decrease in contrast ratio. .
[0114]
FIG. 11 shows a case where the display device is in a mirror state. When the display device is in the mirror state, the transmission polarization axis variable unit 400 turns on the changeover switch 813 so that the liquid crystal layer 407 constituting the display device is turned on. In this case, the external light 3002 from the observer side toward the display device is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed, and the second linearly polarized light component. Only is transmitted and enters the transmission polarization axis variable unit 400. At this time, the external light 3002 incident on the transmission polarization axis variable unit 400 is transmitted through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and reaches the reflection type polarization selection member 300. Since the reflective polarization selection member 300 transmits the first linearly polarized light component and the second linearly polarized light component is specularly reflected, the external light 3002 is reflected by the reflective polarization selection member 300. The external light 3002 reflected by the reflective polarization selection member 300 passes through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and further passes through the polarization selection member 500 and travels toward the observer. Therefore, the mirror state is realized.
[0115]
At this time, since the image display unit 1000 of the present embodiment includes the absorption-type polarization selection member (polarizing plate) 208, the image light in the dark display region is absorbed by the absorption-type polarization selection member (polarization plate) 208. The reflective polarized light selection member 300 is not reached. Therefore, light leakage from the dark display area can be significantly reduced regardless of the reflection performance of the reflective polarization selection member 300.
[0116]
Of the image light emitted from the image display unit 1000, the image light 3001 emitted from the bright display region passes through the reflective polarization selection member 300 and enters the transmission polarization axis variable unit 400. When the display device is in the mirror state, the transmission polarization axis variable unit 400 is in the on state, and the image light 3001 transmitted through the transmission polarization axis variable unit 400 at this time is the first linearly polarized light without changing the polarization axis. Since the light is transmitted as it is, it is absorbed by the absorption polarization selection member 500 and hardly observed by the observer.
[0117]
That is, in the mirror state, the light from the image display member does not reach the observer, while the external light 3002 incident on the display device from the surroundings is ideally half of the unpolarized light. Since it reflects by the selection member 300 and goes to the observer side, it functions as a bright mirror.
[0118]
Further, the display device of this embodiment has a configuration in which the transmission polarization axis variable unit 400 is turned on and the liquid crystal molecules 407a are raised in the mirror state. In general, in a nematic liquid crystal, the deviation of the polarization axis of light emitted in an oblique direction is smaller when the voltage-on liquid crystal molecules are erected than when the voltage-off liquid crystal molecules are twisted. For this reason, the display device of this embodiment is in the oblique direction of the image light (bright display light) 3001 in the mirror state, as compared with the configuration in which the voltage is turned off in the mirror state described in the prior art. The effect that there is little light leakage of is also acquired.
[0119]
The characteristics of the polarizing plate functioning as the absorption polarization selection member 208 or the absorption polarization selection member 500 are directly related to the image quality in the image display state and the visibility of the mirror in the mirror state. Specifically, the transmittance of the polarizing plate is preferably high because it contributes to the brightness of the image in the image display state and the brightness of the reflected image in the mirror state. The degree of polarization of the polarizing plate is directly related to the contrast ratio in the image display state and the amount of unnecessary reflection of external light. The higher the degree of polarization of the polarizing plate, the higher the contrast ratio of image display and the less unnecessary reflection of external light. Therefore, it is desirable that the degree of polarization of the polarizing plate is high. Even in the mirror state, the higher the degree of polarization, the smaller the leakage of light from the image display member and the higher the contrast ratio of the reflected image, thereby realizing a more visible mirror state. desirable.
[0120]
Therefore, it is desirable to use a polarizing plate having a high transmittance and a high degree of polarization as the polarizing plate used as the absorption-type polarization selection member 208 or the absorption-type polarization selection member 500. However, in general, there is a trade-off relationship as illustrated in FIG. 12 between the transmittance of the polarizing plate and the degree of polarization (Nitto Technical Report, Vol 38, No. 1, May, 2000, pp 11-14). FIG. 12 is a graph showing a general relationship between the transmittance of the iodine-based polarizing plate and the degree of polarization. The horizontal axis represents the transmittance of the polarizing plate, and the vertical axis represents the degree of polarization. For this reason, the selection of the characteristics of the polarizing plates used as the absorption-type polarization selection member 208 and the absorption-type polarization selection member 500 is extremely important for achieving both image quality in the image display state and mirror performance in the mirror state.
[0121]
3 and 4 are graphs showing light leakage from the image display unit 1000 in the mirror state. FIG. 3 shows the light leakage magnitude of the bright display portion and FIG. 4 shows the luminance value of the dark display portion. These graphs show a luminance value of 4500 cd / m when the display device is in the image display state. ² The horizontal axis indicates the position on the display device display unit, and the vertical axis indicates the luminance value in the front direction. In the figure, the A type polarizing plate, the B type polarizing plate, and the C type polarizing plate indicate the type of polarizing plate used as the absorbing polarization selecting member 208. For comparison, the absorbing polarizing selection member 208 is eliminated, and other configurations. Shows the light leakage when the same as the display device of the first embodiment. 3 and 4, the A type polarizing plate has a transmittance of 41.5% and a polarization degree of 99.97%, the B type polarizing plate has a transmittance of 43.6%, the polarization degree of 99.5%, the C type polarizing plate has a transmittance of 45.4% and a polarization degree of 96.60%. It is. In the data of FIGS. 3 and 4, an A-type polarizing plate is used as the absorption-type polarization selection member 500.
[0122]
As shown in FIG. 3 and FIG. 4, any polarizing plate of A type, B type, and C type is provided with the absorbing polarization selection member 208, compared to the case without the absorbing polarization selection member 208. It can be seen that light leakage is remarkably reduced, and a mirror that reflects a reflected image with a high contrast ratio can be realized. Particularly, in the case of A-type and B-type polarizing plates having a polarization degree of 99.5% or more, as shown in FIG. 4, the leakage of light in the dark display portion is remarkably reduced, and a high-quality image that reflects a higher contrast ratio is displayed. It can be seen that the mirror state can be realized.
[0123]
Accordingly, the polarization degree of the polarizing plate used as the absorption polarization selection member 208 is preferably at least 96.60% or more, and more preferably 99.5% or more in order to realize a higher quality mirror state. .
[0124]
On the other hand, FIG. 13 shows the relationship between the degree of polarization of the polarizing plate used as the absorption polarization selection member 500, the reflectance of the mirror in the mirror state, and the reflectance of external light (unnecessary reflectance) in the image display state. It is a graph. The horizontal axis represents the degree of polarization of the polarizing plate used as the absorption polarization selection member 500, and the vertical axis represents the reflectance. As shown in FIG. 13, the reflectivity in the mirror state is improved by about 10% by lowering the degree of polarization of the polarizing plate used as the absorption type polarization selection member 500 from 99.97% to 96.60% to achieve higher transmittance. A brighter mirror can be realized. At this time, the increase in unnecessary reflectance in the image display state was small.
[0125]
FIG. 14 is a graph showing an example of the relationship between the degree of polarization of the polarizing plate used as the absorption polarization selection member 208 and the brightness value of the bright display in the image display state. The horizontal axis represents the degree of polarization of the polarizing plate, and the vertical axis represents the relative value. Indicates brightness. Note that the data in FIG. 14 is data when an A-type polarizing plate is used as the absorption-type polarization selection member 500. As shown in FIG. 14, the polarization value of the polarizing plate used as the absorbing polarization selection member 208 is reduced from 99.97% to 96.60% to have a high transmittance, thereby increasing the luminance value by about 9.5% and making it brighter. An image was obtained. This relationship was the same when the characteristics of the polarizing plate of the absorption polarization selection member 208 were fixed and the polarization degree of the polarizing plate of the absorption polarization selection member 500 was changed.
[0126]
In addition, if a polarizing plate having a polarization degree of 99.5% or more is used in one of the absorption polarization selection member 208 and the absorption polarization selection member 500, the polarization degree of the other polarization plate is 96.6% or less. A sufficient contrast ratio was obtained. Accordingly, in order to improve the luminance while maintaining a sufficient contrast ratio in the image display state, polarized light having a high degree of polarization is applied to either the polarizing plate of the absorption polarization selection member 208 or the absorption polarization selection member 500. It is effective to use a plate and a polarizing plate with a low degree of polarization.
[0127]
From the above, when the polarization degree of the polarizing plate of the absorption polarization selection member 208 is P1, and the polarization degree of the polarization plate of the absorption polarization selection member 500 is P2, the brightness and contrast ratio of the display image in the image display state, and In order to satisfy both the contrast ratio and the brightness of the reflected image in the mirror state at a high level, it is desirable to satisfy the following conditions.
Condition 1 0.966 ≦ P1 ≦ 0.995 ≦ P2.
Condition 2 0.966 ≦ P2 ≦ 0.995 ≦ P1 is satisfied, and the image display member is always darkly displayed in the mirror state.
[0128]
The reason why the image display member is always darkly displayed in the mirror state in Condition 2 is that when the polarization degree of the polarizing plate of the absorption-type polarization selection member 500 is low, light leakage from the bright display region increases and reflection occurs. This is because the contrast ratio of the image is significantly reduced. Therefore, by performing dark display, light leakage is prevented and a reduction in contrast ratio is prevented.
[0129]
In the display device according to the first embodiment, a switching unit that links the switching of the lighting switch 100 with the switching switch 813 of the transmission polarization axis variable unit 400 is provided so that the lighting device is turned on in the case of a full mirror state. It may be turned off. In this case, since no light is output from the image display unit 1000, an easy-to-see mirror that can obtain a reflected image with no light leakage and a high contrast ratio can be realized, and power consumption of the display device can be reduced by the amount of light that is turned off. .
[0130]
When only a part of the screen is in a mirror state and an image is displayed in the remaining part, the illumination device is not turned off, and the area of the image display unit 1000 corresponding to the mirror state area is darkly displayed. Thus, it is possible to realize a mirror that realizes a reflected image with a high contrast ratio and a bright image display area on the same screen.
[0131]
As described above, according to the display device of the present invention, the reflective polarization selection member 300 is switched between an effectively transparent state and a state functioning as a mirror by controlling the polarization state by the transmission polarization axis variable unit 400. It is done. Therefore, in the image display state, a bright image can be obtained by effectively setting the reflective polarization selection member 300 in a transparent state. In addition, even in a bright environment, external light is hardly reflected by the display device, so that there is no image quality deterioration such as reflection as in the case of using a half mirror and a reduction in contrast ratio. That is, switching between the image display state and the mirror state can be realized without degrading the performance of each other.
[0132]
In addition, since the image display unit 1000 of the present embodiment includes the absorption-type polarization selection member (polarizing plate) 208, the image light in the dark display region is absorbed by the absorption-type polarization selection member (polarization plate) 208, The reflective polarization selection member 300 is not reached. Therefore, the leakage of light from the dark display area in the mirror state can be greatly reduced regardless of the reflection performance of the reflective polarization selection member 300.
[0133]
In the above-described embodiment, the absorption-type polarization selection member 500 transmits the second linear polarization component and absorbs the first linear polarization component whose polarization axis is orthogonal to the absorption-type polarization selection member 500. 500 may be used so that the first linearly polarized light component is transmitted and the second linearly polarized light component is absorbed. In this case, the transmission polarization axis variable unit 400 is in a mirror state when no voltage is applied to the liquid crystal layer 407, that is, in the off state, and the transmission polarization axis variable unit 400 is in a state where the voltage is applied to the liquid crystal layer 407, that is, in the on state. Make the image display state. That is, it can be in a mirror state when the power of the entire display device is turned off. This is very advantageous when the display device is adopted in a device such as a handheld PC or a cellular phone that requires as little power consumption as possible because the mirror function can be realized without power consumption.
[0134]
In the display device according to the first embodiment, in order to reduce the reflection of light at the interface between the constituent members, each member can be optically coupled with a transparent adhesive having a combined refractive index. .
[0135]
(Example 2)
A display device with a function of switching to the mirror state according to the second embodiment of the present invention will be described with reference to FIGS. The display device of Example 2 has the same basic configuration as the display device shown in FIGS. 1 and 2 of the second embodiment. That is, in the display device of the second embodiment, the absorption polarization selection member 500 of the display device described in the first embodiment is replaced with a combination of a reflection polarization selection member 301 and a variable polarization selection member 600. Accordingly, the same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0136]
As shown in FIGS. 15 and 16, the configuration of this display device is such that the first linearly polarized light component is reflected and the second linearly polarized light is reflected instead of the absorptive polarization selection member 500 of the display device of the first embodiment. The reflection type polarization selection member 301 that transmits the component, and the first linearly polarized light component of the incident light is absorbed, the second linearly polarized light component is transmitted, and the entire polarized light component is transmitted. A variable polarization selection member 600 that can be selected in a state is arranged in order from the transmission polarization axis variable unit 400 side.
[0137]
An observer observes the display device from the variable polarization selection member 600 side (left side in the figure).
[0138]
As the image display unit 1000, an image display unit that includes a liquid crystal display panel 200 that displays an image by adjusting the amount of transmitted light and a lighting device 100 disposed on the rear surface thereof can be used.
[0139]
In the second embodiment, the case where an edge light system is used as the lighting device 100 and a TN liquid crystal display panel is used as the display panel 200, as in the first embodiment, will be described with reference to FIG. It is not limited to this.
[0140]
The reflection-type polarization selection member 300 and the reflection-type polarization selection member 301 transmit a predetermined linearly polarized light component and mirror-reflect a linearly polarized light component having a polarization axis perpendicular thereto. As such a member, the birefringent reflective polarizing film described in Example 1 or a member in which a cholesteric liquid crystal layer and a quarter wavelength plate are laminated on the front and back thereof can be used.
[0141]
In addition, as the reflective polarization selection member 300 and the reflective polarization selection member 301, when using a film-like member such as a refractive reflective polarizing film or a laminated member of a film-like cholesteric liquid crystal layer and a quarter-wave plate, Do as follows. That is, since the film-like reflective polarization selection member is low in flatness as it is, a transparent base that is transparent and optically isotropic is transparent and transparent and has a high rigidity and flatness such as a glass plate or a plastic plate. It is desirable to adhere and fix to the material so that there is no distortion. The film-like reflective polarization selection member 300 and the reflective polarization selection member 301 may be adhesively fixed to a substrate of another adjacent member such as a transparent substrate of the liquid crystal display panel 200.
[0142]
The transmission polarization axis variable unit 400 changes the polarization axis when the incident linearly polarized light is transmitted and changes the polarization axis to the linearly polarized light whose polarization axis is orthogonal to the incident linearly polarized light. The liquid crystal element described in (Embodiment 1) can be used.
[0143]
In the present embodiment, the transmission polarization axis variable unit 400 is disposed between the reflective polarization selection member 300 and the reflective polarization selection member 301. The reflective polarization selection member 300 and the reflective polarization selection member 301 are members that function as reflective surfaces when the display device is in a mirror state. For this reason, when the interval between the reflection type polarization selection member 300 and the reflection type polarization selection member 301 becomes large, parallax occurs in the images reflected by the reflection type polarization selection member 300 and the reflection type polarization selection member 301, respectively. It is desirable to make it smaller. That is, it is desirable that the thickness of the transmission polarization axis variable unit 400 disposed between the reflective polarization selection member 300 and the reflective polarization selection member 301 be as thin as possible.
[0144]
The display device of the second embodiment is mainly used for a person to observe his / her face in a mirror state. Since the average height of all adult male faces is 234.6 mm (Ergonomics Numerical Formula Manual; 1992, published by Gihodo), the vertical distance from the eye to the edge of the face is assumed to be half that of 117.3 mm. The distance between the display device in the mirror state and the eye is 300 mm, and “the definition of the resolution of the average visual acuity of 1.0 is a minimum of one minute in terms of viewing angle” (definition of visual acuity; 1909 International Ophthalmological Society) In view of the above, it is desirable that the interval between the reflective polarization selection member 300 and the reflective polarization selection member 301 is 0.11 mm or less from geometric calculation in order not to feel parallax.
[0145]
That is, when a glass substrate having a thickness of 0.7 mm, which is currently used for a liquid crystal element, is used as the transparent substrates 401 and 402 of the transmission polarization axis variable unit 400, the image reflected when the display device is in a mirror state is parallax. Will result. Therefore, in order to realize a mirror having no parallax in practice, it is desirable to use a transparent substrate of 0.05 mm or less as the transparent substrates 401 and 402. As such transparent substrates 401 and 402, glass or a polymer film can be used. As the polymer film, it is possible to use triacetyl cellulose, an unstretched polycarbonate film formed by a casting method (solution casting method), or the like, which has no optical anisotropy.
[0146]
Alternatively, if the reflective polarization selection member 300 and the reflective polarization selection member 301 are arranged closer to the liquid crystal layer 407 than the transparent substrates 401 and 402 and the liquid crystal layer 407 is sandwiched therebetween, the reflective polarization selection member 300 and the reflective type are selected. Since the distance from the polarization selection member 301 is about the thickness of the liquid crystal layer, a mirror state without parallax can be realized.
[0147]
In addition, since some parallax is permitted depending on a use, this invention does not exclude the case where the space | interval of the reflection type polarization selection member 300 and the reflection type polarization selection member 301 is not said value.
[0148]
On the other hand, the variable polarization selection member 600 absorbs the first linearly polarized light component of the incident light, transmits the second linearly polarized light component whose polarization axis is orthogonal to this, and transmits all the polarized light components. It is a member that can select any one of the states. As such a portion, a guest-host liquid crystal element can be used. Here, a variable polarization selection member 600 using a guest-host type liquid crystal element will be described with reference to FIGS.
[0149]
A variable polarization selection member 600 using a guest-host liquid crystal element includes a first transparent substrate 601 on which a transparent electrode 603 made of ITO and an alignment film 604 made of a polyimide polymer are entirely laminated, and a transparent electrode 606. And a second transparent substrate 602 in which an alignment film 605 is laminated over the entire surface, and a guest-host type liquid crystal layer 607 sandwiched therebetween.
[0150]
Note that the transparent electrodes 603 and 606 formed on the two transparent substrates 601 and 602 are connected to a power source through wiring and a changeover switch 600a, respectively, and the voltage is not applied to the transparent electrodes 603 and 606, and the voltage One of the states to apply can be selected. In other words, the transparent electrodes 603 and 606 have no potential difference and no electric field is applied to the liquid crystal layer 607, and either the voltage is applied to the transparent electrodes 603 and 606 and the electric field is applied to the liquid crystal layer 407. It is configured to be selectable.
[0151]
In the liquid crystal layer 607, two transparent substrates 601 and 602 are arranged so that the alignment film forming surfaces face each other, and a certain gap is provided between the two transparent substrates 601 and 602 with a spacer (not shown) interposed therebetween. The space around the gap is sealed with a sealant 610 to form a space, and guest-host type liquid crystal is sealed in the space.
[0152]
Here, the operation of the variable polarization selection member 600 will be described with reference to FIGS. 17 and 18 are partially schematic cross-sectional views showing an example of the variable polarization selection member 600. FIG. The guest-host type liquid crystal layer 607 is obtained by adding a dichroic dye 6071 to the nematic liquid crystal 6072 as a guest. In this embodiment, a liquid crystal having positive dielectric anisotropy is used as the nematic liquid crystal, and the alignment direction of the long axis of the liquid crystal molecule is substantially horizontal with respect to the substrates 601 and 602 by the rubbing alignment films 604 and 605, and An orientation without twisting between the two transparent substrates 601 and 602, that is, a homogeneous orientation is adopted. At this time, a pretilt is applied so that the alignment directions in the vicinity of the two transparent substrates 601 and 602 are parallel to each other. The pretilt angle is desirably 2 ° or more so that reverse tilt does not occur. Here, a pretilt of about 4 ° is applied.
[0153]
Here, the dichroic dye 6071 has a rod-like structure and has a property of being aligned in a direction parallel to the liquid crystal molecules. Therefore, for example, when the orientation of the liquid crystal molecules is changed from the horizontal direction to the vertical direction with respect to the substrate, the orientation of the dichroic dye also changes from the horizontal direction to the vertical direction accordingly. Here, a guest host liquid crystal material LA121 / 4 (trade name) manufactured by Mitsubishi Kasei Co., Ltd. was used as the liquid crystal layer 607, and the thickness of the liquid crystal layer 607 was 5 μm.
[0154]
FIG. 17 shows a state in which there is no potential difference between the transparent electrodes 603 and 606 formed on the two transparent substrates 601 and 602 and no electric field is applied to the liquid crystal layer 607, that is, the changeover switch 600a is in an off state. In this case, the nematic liquid crystal 6072 of the liquid crystal layer 607 is in an initial alignment state, that is, a homogeneous alignment substantially horizontal to the substrate (left and right direction in the drawing), and the dichroic dye 6071 is aligned accordingly. The dichroic dye 6071 has an absorption polarization axis substantially parallel to the molecular axis, and has a property of strongly absorbing a polarization component parallel to the molecular axis and hardly absorbing a polarization component orthogonal thereto. For this reason, incident light 5000 having various polarization planes that enter from a substantially vertical direction with respect to the transparent substrate surface has an oscillation direction of an electric vector parallel to the molecular axis of the dichroic dye 6071 when passing through the liquid crystal layer 607. The linearly polarized light component Lp is absorbed, and the linearly polarized light component Ls orthogonal thereto is transmitted.
[0155]
FIG. 18 shows a state where a voltage is applied to the transparent electrodes 603 and 606 formed on the two transparent substrates 601 and 602, respectively, and an electric field is applied to the liquid crystal layer 607, that is, the changeover switch 600a is turned on. In this case, the alignment direction of the molecular long axis of the nematic liquid crystal 6072 changes from the horizontal direction to the vertical direction with respect to the two transparent substrates 601 and 602, and accordingly, the alignment direction of the dichroic dye 6071 also changes in the vertical direction. To do. For this reason, the incident light 5000 having various polarization planes that are incident from substantially the vertical direction with respect to the transparent substrate surface transmits most of the polarization components without being absorbed. At this time, in this example, the voltages applied to the transparent electrodes 603 and 606 of the transparent substrates 601 and 602 were ± 30 V and 60 Hz.
[0156]
Therefore, if the alignment direction of the liquid crystal molecules is made coincident with the polarization axis of the first linearly polarized light, the first linearly polarized component of the incident light is absorbed and the second linearly polarized light component whose polarization axis is orthogonal to this is absorbed. Can realize a variable polarization selection member capable of selecting either a state of transmitting or a state of transmitting all polarized components.
[0157]
The variable polarization selection member 600 is preferably subjected to a process for suppressing regular reflection on the surface thereof in order to suppress deterioration in image quality due to reflection of external light. However, what is important here is that the display device of the present invention also functions as a mirror. Therefore, as a treatment for preventing regular reflection of the variable polarization selection member 600, a fine unevenness is formed on the surface or a transparent fine particle is contained on the surface. A method of reducing the specular reflection component by forming a resin layer is not desirable. This is because, when such processing is performed, the image display performance is improved by reducing the reflection, but the image reflected in the mirror is blurred and the mirror performance deteriorates. Accordingly, it is desirable to form an antireflection film on the surface of the variable polarization selection member 600 for preventing regular reflection. A known technique can be used as the antireflection film. That is, it is possible to use a method in which several types of optically designed metal oxides having different refractive indexes are multilayer-coated by vapor deposition, or a method in which a low refractive index material such as a fluorine compound is applied.
[0158]
FIG. 19 is an explanatory view of the axis direction of each member of the present embodiment. In addition, the display of the angle of each axis is indicated by the counterclockwise angle from the 3 o'clock position in the horizontal direction of the image display surface. As shown in FIG. 19, the transmission polarization axis of linearly polarized light of the absorption-type polarization selection member (polarizing plate) 208 of the TN liquid crystal display panel 200 constituting the image display unit 1000 is set to 135 °. Accordingly, the transmission polarization axis of the linearly polarized light of the reflective polarization selection member 300 is also 135 °, and the alignment directions of the liquid crystal molecular major axes on the transparent substrate 402 side and the transparent substrate 401 side of the transmission polarization axis variable unit 400 are 135 ° respectively. 45 °, the transmission polarization axis of the linearly polarized light of the reflective polarization selection member 301 is 45 °, and the alignment directions of the major axis of liquid crystal molecules on the transparent substrate 602 side and the transparent substrate 601 side of the variable polarization selection member 600 are both 135 °.
[0159]
Next, the operation of the display device according to the second embodiment will be described with reference to the drawings. 20 and 21 are schematic configuration diagrams for explaining the basic configuration and operation of the display device.
[0160]
In this embodiment, the variable polarization selection member 600 absorbs the first linearly polarized light component (up and down direction in the drawing) in the off state, and the second linearly polarized light component (in the drawing perpendicular direction to the drawing in the drawing). ) Describes the case of transmitting and transmitting all polarized components in the on state.
[0161]
Further, as the transmission polarization axis variable unit 400, in the off state, when the incident linearly polarized light is transmitted, the polarization axis is changed, and the incident linearly polarized light is changed to linearly polarized light whose polarization axis is orthogonal, A case where the polarization axis is not changed in the on state will be described.
[0162]
FIG. 20 shows the case of the image display state. When the display device is in an image display state, the transmission polarization axis variable unit 400 is in a state where no voltage is applied to the liquid crystal layer 407 constituting the display device, that is, in an off state. The variable polarization selection member 600 is also turned off.
[0163]
As described above, the image display unit 1000 includes the illumination device 100 disposed on the back surface of the liquid crystal display panel 200. The image display unit 1000 emits from the illumination device 100 and is an absorption-type polarization selection member (polarizing plate) of the liquid crystal display panel 200. ) The first linearly polarized light transmitted through 208 is emitted from the image display unit 1000 as image light 3001. The image light 3001 composed of the first linearly polarized light emitted from the image display unit 1000 passes through the reflective polarization selection member 300 and enters the transmission polarization axis variable unit 400.
[0164]
The image light 3001 passing through the transmission polarization axis variable unit 400 changes from the first linearly polarized light to the second linearly polarized light. The image light 3001 transmitted through the transmission polarization axis variable unit 400 is incident on the reflection type polarization selection member 301. The reflective polarization selection member 301 mirror-reflects the first linearly polarized light component but transmits the second linearly polarized light component. Therefore, the image light 3001 changed to the second linearly polarized light by the transmission polarization axis variable unit 400. Passes through the reflective polarization selection member 301 and enters the variable polarization selection member 600. When the display device is in the image display state, the variable polarization selection member 600 is in the off state, and the first linearly polarized light component is absorbed in the light incident thereon, but the second linearly polarized light component is transmitted. Therefore, the image light 3001 passes through the variable polarization selection member 600 and is observed by the observer.
[0165]
On the other hand, external light 3002 directed from the observer side (left side in the figure) toward the display device is non-polarized light. However, when the display device is in an image display state, the variable polarization selection member 600 is in an off state, and light incident on this is input. The first linearly polarized light component is absorbed and only the second linearly polarized light component is transmitted. The external light 3002 that has passed through the variable polarization selection member 600 passes through the reflection-type polarization selection member 301 and passes through the transmission polarization axis variable unit 400, changing from the second linearly polarized light to the first linearly polarized light. The reflective polarization selection member 300 is also transmitted and hardly returns to the viewer side toward the image display unit 1000.
[0166]
Therefore, in the image display state, the image light 3001 emitted from the image display unit 1000 is directed to the observer with almost no loss, so that a bright image can be obtained. Further, since the external light 3002 is hardly reflected by the display device, the image quality is not deteriorated due to external light such as reflection and a decrease in contrast ratio.
[0167]
FIG. 21 shows a case where the display device is in a mirror state. When the display device is in a mirror state, the transmission polarization axis varying unit 400 applies a voltage to the liquid crystal layer 407 constituting the display device to turn it on. The variable polarization selection member 600 is also turned on.
[0168]
Also in this case, the image light 3001 corresponding to the bright display emitted from the image display unit 1000 and transmitted through the reflective polarization selection member 300 enters the transmission polarization axis variable unit 400. At this time, the image light 3001 transmitted through the transmission polarization axis variable unit 400 is transmitted as the first linearly polarized light without changing the polarization axis, reflected by the reflective polarization selection member 301, and returned to the image display unit 1000. , Not observed by the observer.
[0169]
On the other hand, the external light 3002 from the observer side toward the display device is outside light because the variable polarization selection member 600 is in an on state when the display device is in a mirror state, and is transparent to most polarization components. Most of 3002 is transmitted through the variable polarization selection member 600. The external light 3002 that has passed through the variable polarization selection member 600 is incident on the reflective polarization selection member 301. Of the external light 3002 incident on the reflection type polarization selection member 301, the second linear polarization component is transmitted through the reflection type polarization selection member 301, and the first linear polarization component is reflected by the reflection type polarization selection member 301. Then, the light passes again through the variable polarization selection member 600 and moves toward the viewer. On the other hand, out of the external light 3002 incident on the reflective polarization selection member 301, the second linearly polarized light component transmitted through the reflective polarization selection member 301 is transmitted through the transmission polarization axis variable unit 400 without changing the polarization axis. The light is reflected by the reflective polarization selection member 300, passes through the transmission polarization axis variable unit 400, the reflective polarization selection member 301, and the variable polarization selection member 600 again, and travels toward the viewer.
[0170]
That is, in the mirror state, the image light 3001 is reflected by the reflective polarization selection member 301 and returns to the image display unit 1000 so that it is not observed by the observer. The external light 3002 functions as an extremely bright mirror because most of the polarization components are reflected by the first reflective polarization selection member 300 and the reflective polarization selection member 301.
[0171]
As in the first embodiment, in this embodiment, when the display device is in a mirror state, the corresponding portion of the image display unit 1000 is darkly displayed or the illumination device 100 constituting the image display member is turned off. It can be configured to perform such operations in conjunction with the above operation. In this case, since image light is not output from the image display unit 1000, stray light unnecessary for the observer does not impair the performance of the mirror, and particularly when the illumination device 100 is turned off, power consumption can be reduced in the mirror state. There is also an effect.
[0172]
As described above, in the display device of this embodiment, the reflective polarization selection member 300 and the reflective polarization selection member 301 are configured to control the absorption of polarized light by the variable polarization selection member 600 and the polarization state by the transmission polarization axis variable unit 400. By controlling the above, it is possible to switch between an effectively transparent state and a state that functions as a mirror. Therefore, in the image display state, the reflection-type polarization selection member 300 and the reflection-type polarization selection member 301 are effectively transparent to obtain a bright image, and the outside light is displayed even in a bright environment. Since it is hardly reflected by the apparatus, there is no deterioration in image quality such as a reflection as in the case of using a half mirror and a reduction in contrast ratio. That is, switching between the image display state and the mirror state can be realized without degrading the performance of each other.
[0173]
In particular, in this embodiment, when the display device is in a mirror state, the variable polarization selection member 600 is in a transparent state, and most of the polarization component of the external light is reflected by the reflection type polarization selection member 301 and the reflection type polarization selection member 300. Therefore, there is an effect that an extremely bright mirror that is twice or more that of the display device of the first embodiment can be realized.
[0174]
In addition, in order to reduce the interface reflection of each member which comprises this display apparatus, it is also possible to make it the structure which couple | bonds each member optically with the transparent adhesive which match | combined the refractive index.
[0175]
In the above embodiment, the liquid crystal layer 607 of the variable polarization selection member 600 has a homogeneous alignment using a liquid crystal having a positive dielectric anisotropy as a nematic liquid crystal. However, the liquid crystal layer 607 has a negative dielectric anisotropy as a nematic liquid crystal. It is also possible to use a liquid crystal having a homeotropic alignment in which the direction of the major axis of the liquid crystal molecule is substantially perpendicular to the transparent substrate in the initial state (state where no electric field is applied). In this case, when a voltage is applied to the transparent electrodes 603 and 606 of the two transparent substrates 601 and 602 and an electric field is applied to the liquid crystal layer 607, the alignment direction of the liquid crystal molecule major axis is applied to the two transparent substrates 601 and 602. On the other hand, although it changes from the vertical direction to the horizontal direction, it is preferable to give a slight pretilt angle to the initial alignment state of the liquid crystal so that the liquid crystal molecules are aligned in a certain direction.
[0176]
When a liquid crystal having negative dielectric anisotropy is used as the nematic liquid crystal of the liquid crystal layer 607 and homeotropic alignment is used, there is no potential difference between the transparent electrodes 603 and 606 of the two transparent substrates 601 and 602, and an electric field is applied to the liquid crystal layer 607. In the state in which no is applied, that is, in the off state, the nematic liquid crystal of the liquid crystal layer 607 has the molecular long axis direction substantially perpendicular to the transparent substrate, and the dichroic dye is aligned accordingly. Therefore, incident light from the outside passes through the liquid crystal layer 607 with almost no absorption.
[0177]
On the other hand, when a voltage is applied to the transparent electrodes 603 and 606 of the two transparent substrates 601 and 602 and an electric field is applied to the liquid crystal layer 607, that is, in the ON state, the alignment direction of the molecular long axis of the nematic liquid crystal is two transparent With respect to the substrates 601 and 602, the direction changes from the vertical direction to the horizontal direction, and the orientation direction of the dichroic dye also changes in the horizontal direction. The dichroic dye has an absorption polarization axis substantially parallel to the molecular axis, and has a property that a polarization component parallel to the molecular axis is strongly absorbed and a polarization component orthogonal to this is hardly absorbed. Therefore, when the incident light from the outside passes through the liquid crystal layer 607, the linearly polarized light component having the vibration direction of the electric vector in the direction parallel to the molecular axis of the dichroic dye is absorbed, and the linearly polarized light component orthogonal to this is absorbed. To Penetrate.
[0178]
That is, if the alignment direction of the liquid crystal in a state where an electric field is applied to the liquid crystal layer 607 coincides with the polarization axis of the first linearly polarized light, the first linearly polarized component of the incident light is absorbed and the second straight line is absorbed. It is possible to realize a variable polarization selection member capable of selecting either a state where the polarization component is transmitted or a state where all the polarization components are transmitted.
[0179]
In the second embodiment, the case where the variable polarization selection member 600 is arranged on the viewer side of the reflective polarization selection member 301 has been described. The variable polarization selection member is an important member that suppresses unnecessary reflection of external light from the reflection type polarization selection member 301 in the image display state, and is effectively transparent in the mirror state and contributes to improving the brightness of the mirror. is there. However, in consideration of various applications, the present invention does not exclude a configuration in which the variable polarization selection member 600 is not disposed on the viewer side of the reflective polarization selection member 301. In this case, in the image display state, external light may be reflected by the reflective polarization selection member 301 and the image may be difficult to see, but in the mirror state, the external light is reflected by the reflective polarization selection member and the reflective polarization selection member 301. An extremely high reflectance of 80% or more was obtained because there was no member that hindered reflection of light. This reflectivity is comparable to that of a mirror in which an aluminum thin film is formed on a glass substrate, and a mirror having the same brightness as a general mirror can be realized.
[0180]
(Mirror area size)
Here, in the case where the display devices of the first and second embodiments are mainly used for the viewer to view and observe his / her face when in the mirror state, a desired mirror region size is obtained. Considering that the average height of all adult male faces is 234.6 mm and the average head width is 156.4 mm (Ergonomic Reference Manual of Numerical Expressions; 1992, published by Gihodo), the observer can change the observation position. In order to reflect the entire face in the mirror without changing, the mirror must have a size of 117.3 mm in height and 78.2 mm in width or more.
[0181]
The display device according to the present invention has an image display state and a mirror state by the transmission polarization axis variable unit 400 in (Example 1) and by the transmission polarization axis variable unit 400 and the variable polarization selection member 600 in (Example 2). Switching is in progress. Therefore, in order to realize the mirror region of the above size, the transparent electrodes 403 and 406 formed on the two transparent substrates 401 and 402 constituting the transmission polarization axis variable unit 400, respectively, and the variable polarization selection member 600 It is desirable that the transparent electrodes 603 and 606 formed on the two transparent substrates 601 and 602 are continuously formed at least with respect to a region having a height of 117.3 mm and a width of 78.2 mm or more. For example, if the transparent electrode is divided and formed within this region, for example, a portion of the transparent electrode functions as a mirror, but the gap between the transparent electrodes does not function as a mirror, and the gap is streaked. This is because, when observed, satisfactory performance as a mirror cannot be obtained.
[0182]
When the display devices of the first and second embodiments are used in a portable device such as a mobile phone or a portable information terminal, the size of the display device itself is 117.3 mm in height and 78 in width as described above. .It may be less than 2 mm. Therefore, instead of projecting the entire face, it is possible to obtain a mirror size that is suitable for use in, for example, partially correcting makeup or checking contact lenses in the eyes. it can. In this case, the size may be such that a quarter of the face appears in the mirror. Specifically, it is desirable that the mirror has a height of 58.6 mm and a width of 39.1 mm or more.
[0183]
Accordingly, the transparent electrodes 403 and 406 formed on the two transparent substrates 401 and 402 constituting the transmission polarization axis variable unit 400 and the two transparent substrates 601 and 602 of the variable polarization selection member 600 are formed. Further, it is desirable that the transparent electrodes 603 and 606 are continuously formed so as not to be chipped with respect to a region having a height of at least 58.6 mm and a width of 39.1 mm or more.
[0184]
(Example 3)
In the display devices of the first and second embodiments described above, the image display unit 1000 that emits the first linearly polarized light as image light is configured to use a liquid crystal display panel in which an illumination device is disposed on the back surface. The invention is not limited to this.
[0185]
As the image display unit 1000 that emits linearly polarized light as image light, a rear projection display device using a liquid crystal display panel as a two-dimensional optical switch element can be used. The third embodiment uses a rear projection display device as the image display unit 1000 of the display device described in the first embodiment, and the same parts as those in the first embodiment are denoted by the same reference numerals and detailed description thereof is omitted. .
[0186]
As shown in FIG. 22, this display device includes a transmission screen 703, a projection device 701, and a mirror 702, and projection light 704 emitted from the projection device 701 irradiates the transmission screen 703 via the mirror 702. It has become a structure. The transmissive screen 703 includes the reflective polarization selection member 300 according to the first embodiment, the transmission polarization axis variable unit 400, and the absorption polarization selection member 500.
[0187]
The projection device 701 can use a liquid crystal projection device using a liquid crystal display panel as a two-dimensional optical switch element. The projection device 701 uses light that emits linearly polarized light in which the polarization state of each color light matches as the projection light. Further, the image light 704 emitted from the projection device 701 is configured to be s-polarized light or p-polarized light with respect to the reflection surface of the mirror 702. In general, the light incident on the reflecting surface has a phase difference between the s-polarized component and the p-polarized component with respect to the reflecting surface. Therefore, s-polarized light or polarized light other than p-polarized light is incident on the reflecting surface. This is because the polarization state changes.
[0188]
As the mirror 702, an optically isotropic transparent glass deposited with a reflective metal such as silver or aluminum can be used.
[0189]
As shown in FIG. 23, the transmission screen 703 includes a Fresnel lens sheet 1402, a lenticular lens sheet 1401, a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and an absorption polarization selection member 500 in this order. The arrangement is arranged. The Fresnel lens sheet 1402 is an optical component that has the same function as a convex lens, and functions to widen the appropriate viewing range by bending the principal ray direction from the projection device 701 toward the viewer. The lenticular lens sheet 1401 acts to effectively distribute the limited projection light beam from the projection device 701 to the observation range of the observer. Thereby, a bright image can be obtained.
[0190]
24 and 25, an example of a lenticular lens sheet 1401 that can be used in this embodiment will be described. The lenticular lens sheet 1401 has a configuration in which a plurality of cylindrical lens-like lenses 1501 are arranged in one direction and a black stripe 1502 is provided in a portion other than the light condensing portion, and the focal position of the lens 1501 is set as an observation surface. By doing so, it is ideally configured such that a decrease in contrast ratio with respect to external light can be suppressed without loss of projection light. In general, a lenticular lens sheet can have a wide viewing angle in the horizontal direction by arranging its generatrix so as to be perpendicular to the display surface.
[0191]
Note that both the Fresnel lens sheet 1402 and the lenticular lens sheet 1401 are made of an injection molded product using a member having a low birefringence, for example, an acrylic resin so that the polarization disturbance of the projection light 704 from the projection device 701 is minimized. It is desirable to use it.
[0192]
As described above, the reflective polarization selection member 300 is an important member that functions as a reflection surface of a mirror, and therefore, a transparent, rigid, flat, and optically isotropic transparent substrate that does not distort, for example, has a thickness. A configuration can be adopted in which an injection molded acrylic resin plate or the like of about 3 mm is bonded with an adhesive.
[0193]
The directions of the axes of the reflective polarization selection member 300, the transmission polarization axis variable unit 400, and the absorption polarization selection member 500 are set such that the projection light 704 emitted from the projection device 701 and incident on the transmission screen 703 is the first linear polarization. As described in the first embodiment.
[0194]
Next, the operation of this display device will be described. Here, a case will be described in which the absorption-type polarization selection member 500 absorbs the first linearly polarized light component and transmits the second linearly polarized light component.
[0195]
Since this display device is composed of the same member as that of the first embodiment except that a rear projection type display device is used as the image display member, the operation is also the same. That is, when the display device is in an image display state, the image light 704 emitted from the projection device 701 is reflected by the mirror 702 and enters the transmission screen 703. The image light 704 incident on the transmissive screen 703 is transmitted through the reflective polarization selection member 300 while being effectively spread in the observer's observation range by the action of the Fresnel lens 1402 and the lenticular lens 1401, and the transmissive polarization axis variable unit 400. Is incident on. When the display device is in an image display state, the image light 704 that passes through the transmission polarization axis variable unit 400 changes from the first linearly polarized light to the second linearly polarized light and passes through the absorption-type polarization selection member 500. Observed by an observer.
[0196]
On the other hand, external light traveling from the observer side toward the display device is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed and only the second linearly polarized light component is transmitted. To do. When the external light transmitted through the absorptive polarization selection member 500 passes through the transmission polarization axis variable unit 400, it changes from the second linearly polarized light to the first linearly polarized light and passes through the reflective polarization selection member 300. , The Fresnel lens 1402, the lenticular lens 1401, and further toward the projection device 701 through the mirror 702, hardly return to the viewer side.
[0197]
Therefore, in the image display state, the image light 704 emitted from the projection device 701 and passed through the Fresnel lens 1402 and the lenticular lens 1401 is directed to the observer with almost no loss, so that a bright image can be obtained. Furthermore, since the external light is hardly reflected by the display device, the image quality is not deteriorated due to the external light such as reflection or a reduction in contrast ratio.
[0198]
When the display device is in a mirror state, the image light 704 emitted from the projection device 701 enters the transmission screen 703 via the mirror 702. The image light 704 incident on the transmissive screen 703 is transmitted through the reflective polarization selection member 300 while being effectively spread in the observer's observation range by the action of the Fresnel lens 1402 and the lenticular lens 1401, and the transmissive polarization axis variable unit 400. Is incident on. When the display device is in a mirror state, the image light 704 transmitted through the transmission polarization axis variable unit 400 is transmitted as the first linearly polarized light without changing the polarization axis, and is absorbed by the absorption polarization selection member 500. , Not observed by the observer.
[0199]
On the other hand, the external light from the observer side toward the display device is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed and only the second linearly polarized light component is transmitted. Then, the light enters the transmission polarization axis variable unit 400. The external light incident on the transmission polarization axis variable unit 400 passes through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and reaches the reflection type polarization selection member 300. Since the reflective polarization selection member 300 transmits the first linearly polarized light component and the second linearly polarized light component is specularly reflected, the external light is reflected by the reflective polarization selection member 300. The external light reflected by the reflective polarization selection member 300 is transmitted through the transmission polarization axis variable section 400 as the second linearly polarized light without changing the polarization axis, and is also transmitted through the polarization selection member 500 toward the observer.
[0200]
Therefore, in the mirror state, the image light 704 is absorbed by the absorptive polarization selection member 500 and does not reach the observer. Ideally, the external light incident on the display device is half of the non-polarized light. Since it reflects on the member 300 and goes to the viewer side, it functions as a bright mirror.
[0201]
When the display device is in the mirror state, the image of the projection device 701 is darkly displayed in the region corresponding to the region in the mirror state. In this case, since image light from the projection device 701 hardly leaks, unnecessary light is not directed to the observer, so that a mirror state in which a reflected image with a high contrast ratio is obtained can be realized.
[0202]
In the above description, the absorption polarization selection member 500 transmits the second linear polarization component and absorbs the first linear polarization component. However, the absorption polarization selection member 500 has the first linear polarization component. May be used that transmits and absorbs the second linearly polarized light component. In this case, when the power consumption of the display device is zero, it can function as a mirror.
[0203]
In this embodiment, the transmissive screen 703 includes a Fresnel lens sheet 1402, a lenticular lens sheet 1401, a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and an absorption polarization selection as shown in FIG. The member 500 is arranged in this order. However, apart from this configuration, as shown in FIG. 26, the transmissive screen 703 includes a Fresnel lens sheet 1402, a lenticular lens sheet 1401, a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and a reflective polarization. The selection member 301 and the variable polarization selection member 600 may be arranged in this order. In this case, the rear projection display device is used for the image display unit 1000 of the display device described in the second embodiment, and the same operation and action as described in the second embodiment can be obtained.
[0204]
In addition, the mirror function unit (reflection type polarization selection member 300, transmission polarization axis variable unit 400, reflection type polarization selection member 301, variable polarization selection member 600) and optical system (Fresnel lens) constituting the transmission type screen 703 of this embodiment. Of the sheet 1402 and the lenticular lens sheet 1401), the mirror function unit may be detachable from the optical system, and the mirror function unit may be removed when the mirror function is unnecessary. Alternatively, it is also possible to configure a screen that does not include an image display unit and is provided with a mirror function unit independently, and that this mirror function screen is mounted on an arbitrary display device as necessary.
[0205]
(Example 4)
A display device according to a fourth embodiment of the present invention will be described with reference to FIGS. In the fourth embodiment, conductive metal linear patterns are formed at a pitch of several hundred angstroms on the transparent substrates 401 and 402 (see FIG. 16) of the display device described in the second embodiment. Further, the reflective polarization selection member 301 and the transparent electrode 403, and the reflective polarization selection member 300 and the transparent electrode 406 are combined. Therefore, the same parts as those described above are denoted by the same reference numerals and detailed description thereof is omitted.
[0206]
In the fourth embodiment, an aluminum metal linear pattern is formed on the transparent substrates 401 and 402 of the transmission polarization axis varying means 400 at a pitch of several thousand angstroms. In this case, the light incident on the metal linear pattern reflects the linearly polarized light component parallel to the longitudinal direction of the metal linear pattern, and transmits the linearly polarized light component in the direction orthogonal thereto. Functions as a reflective polarization selection member. Further, by electrically connecting a part of these adjacent linear patterns, the potential can be made the same or substantially the same state, so that it also functions as a transparent electrode that transmits a specific linearly polarized light component. be able to. That is, the metal linear pattern serves both as a reflective polarization selection member and a transparent electrode. It should be noted that the electrical connection between the adjacent linear patterns is performed at a place other than the mirror region such as the peripheral portion so as not to adversely affect the function of the reflective polarization selection member.
[0207]
Here, as shown in FIG. 27, the transmission polarization axis variable portion 400 is formed of the same material as the first transparent substrate 401 in which the metal linear pattern 311 and the alignment film 404 made of a polyimide-based polymer are entirely laminated. The liquid crystal layer 407 includes a second transparent substrate 402 on which the linear pattern 310 and the alignment film 405 are entirely stacked.
[0208]
The metal linear patterns 311 and 310 formed on the two transparent substrates 401 and 402 are connected to a power source via wiring and switching elements (not shown), and a voltage is applied to the metal linear patterns 311 and 310. Either a state where no voltage is applied or a state where a voltage is applied can be selected. That is, there is no potential difference between the metal linear patterns 311 and 310 and no electric field is applied to the liquid crystal layer 407, and no voltage is applied to the metal linear patterns 311 and 310 and an electric field is applied to the liquid crystal layer 407. The state is configured to be selectable. Further, the longitudinal directions of the lines of the metal linear patterns 310 and 311 are configured and arranged so as to be orthogonal to each other.
[0209]
In the liquid crystal layer 407, two transparent substrates 401 and 402 are arranged so that the formation surfaces of the alignment films 404 and 410 face each other, and a spacer (not shown) is sandwiched between the two transparent substrates 401 and 402. A gap is provided, and a space is formed by sealing the periphery of the gap in a frame shape with a sealing material 410, and nematic liquid crystal having positive dielectric anisotropy is sealed in the space.
[0210]
FIG. 28 is an explanatory view of the axis direction of each member of the present embodiment. In addition, the display of the angle of each axis is indicated by the counterclockwise angle from the 3 o'clock position in the horizontal direction of the image display surface. As shown in FIG. 28, the transmission polarization axis of the linearly polarized light of the absorption polarization selection member (polarizing plate) 208 of the TN liquid crystal display panel 200 constituting the image display unit 1000 is set to 135 °. Therefore, the transmission polarization axis of the linearly polarized light of the metal linear pattern 310 functioning as a reflection type polarization selection member is also 135 °, and the liquid crystal molecule major axis of the transmission polarization axis variable unit 400 and the liquid crystal molecule long axis on the transparent substrate 401 side are the same. The orientation directions are 135 ° and 45 °, respectively, the linear polarization transmission polarization axis of the metal linear pattern 311 functioning as a reflective polarization selection member is 45 °, the transparent polarization substrate 602 side and the transparent substrate 601 side of the variable polarization selection member 600. The orientation direction of the major axis of the liquid crystal molecules is 135 °.
[0211]
With the above configuration, in the display device of the fourth embodiment, the metal linear pattern 310 functions as the reflective polarization selection member 300 and the electrode 406 of the second embodiment, and the metal linear pattern 311 is the reflective polarization selection of the second embodiment. In order to fulfill the functions of the member 301 and the electrode 403, the display device of the fourth embodiment operates in the same manner as the display device of the second embodiment, and the same effect can be obtained.
[0212]
As described in the second embodiment, the reflective polarization selection members 300 and 301 are members that function as a reflective surface when the display device is in a mirror state. For this reason, when the interval between the reflection type polarization selection member 300 and the reflection type polarization selection member 301 becomes large, parallax occurs in the image reflected by each of the reflection type polarization selection member 300 and the reflection type polarization selection member 301. It is necessary to make it as small as possible, and it is desirable that it is 0.11 mm or less practically. In the fourth embodiment, a liquid crystal layer 407 of about several μm is formed between the metal linear pattern 310 that functions as the reflective polarization selection member 300 and the metal linear pattern 311 that functions as the reflective polarization selection member 301. Since there are only thin films such as alignment films 404 and 410 of less than 1 μm, the distance between them is less than 10 μm. For this reason, there is an effect that a high-quality mirror having no parallax can be realized.
[0213]
Further, since the metal linear patterns 310 and 311 are formed on a flat substrate such as glass, it is possible to realize a mirror that is less susceptible to environmental changes such as temperature and humidity and is less likely to be distorted due to environmental changes. There is also an effect.
[0214]
In the present invention, the metal linear patterns 310 and 311 only need to be able to obtain uniform reflection in the visible light range, and the specific structure, pitch, pattern height, etc. of the linear pattern are particularly limited. It is not something. Moreover, you may use the metal linear pattern formed with chromium, silver, etc. other than aluminum.
[0215]
(Example 5)
In the first to fourth embodiments, a mirror including the reflective polarization selection member 300, the transmission polarization axis variable unit 400, and the polarization selection member 500 is provided above the image display unit 1000 that emits the first linearly polarized light as image light. The case where the functional unit or the mirror functional unit including the reflective polarization selection member 300, the transmission polarization axis variable unit 400, the reflective polarization selection member 301, and the variable polarization selection member 600 is arranged has been described. In these cases, the image display unit 1000 can display an image even if the mirror function unit is not arranged. Depending on the purpose of use of the device, the mirror function unit can be detachable so that the mirror function is not required. Convenience can be improved, such as removing a functional part.
[0216]
However, the present invention is not limited to these. That is, a configuration that enables image display when there is a mirror function unit, or a configuration in which a partial configuration of the mirror function unit and the image display member is shared may be used.
[0217]
A display device of Example 5 will be described with reference to FIG. Since the fifth embodiment has many common parts with the first embodiment (see, for example, FIG. 8), the same members as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0218]
This display device uses the display device described in Embodiment 1 that can irradiate three primary colors of red, green, and blue in a time-sharing manner as the illumination device 100, and absorbs polarized light from the image display unit 1000 to the viewer side. The selection member (polarizing plate) 208 is removed. Therefore, when the mirror function unit including the reflective polarization selection member 300, the transmission polarization axis variable unit 400, and the absorption polarization selection member 500 is removed, the liquid crystal display panel 200 of this embodiment cannot display a clear image. .
[0219]
The liquid crystal display panel 200 of the present embodiment can correspond to the field sequential color display method in addition to the liquid crystal display panel 200 of the first embodiment except that the absorption-type polarization selection member (polarizing plate) 208 is removed. The response of the liquid crystal can be increased.
[0220]
The details of the field sequential color display system are described in, for example, Japanese Patent Laid-Open Nos. 5-19257 and 11-52354. In this method, a liquid crystal display panel is irradiated with illumination light of three primary colors in a time-sharing manner, and a liquid crystal is driven in synchronization therewith to realize a color image display. That is, since the liquid crystal display panel needs to display three sub-frames corresponding to the three primary colors in order to display one frame, the liquid crystal needs to respond faster. In order to speed up the response of the liquid crystal so as to correspond to the field sequential color display method, for example, when the TN mode is used, a liquid crystal having a large birefringence Δn is used in order to satisfy the above-mentioned waveguide condition, and the thickness of the liquid crystal layer 207 is increased. The thickness may be as thin as about 2 μm.
[0221]
In this embodiment, the case of the TN mode will be described below. However, the liquid crystal display panel of the present invention is not limited to the above configuration as long as the response characteristic corresponding to the field sequential color display method can be obtained. Absent.
[0222]
The illumination device 100 includes a light guide 193 made of a transparent medium, a light source 190 that emits light of three primary colors of red, green, and blue disposed on an end surface of the light guide 193, and a polarization that is disposed on the back surface of the light guide 193. The sustain reflection sheet 192 and the polarization maintaining diffusion unit 191 disposed on the front surface of the light guide 193 are configured.
[0223]
As the light source 190 that emits light of three primary colors of red, green, and blue, an LED (Light Emitting Diode) in which three chips that emit light of the three primary colors are integrated can be used. Such LED is marketed by Nichia Corporation.
[0224]
The light guide 193 is made of a transparent acrylic resin and radiates light toward the liquid crystal display panel 200 by changing the reflection angle of the light propagating through the configuration in which light incident from the end face is confined inside by total reflection. The back surface (the surface on the side opposite to the liquid crystal display panel 200) is provided with an inclined reflection surface 194 formed of a number of uneven surfaces or steps having fine inclined surfaces. This is for maintaining the polarization state of the light incident on the light guide 193 from the liquid crystal display panel 200 side for the reason described later.
[0225]
The inclined reflecting surface 194 is preferably a mirror reflecting surface made of a metal thin film such as aluminum or silver, or a dielectric multilayer film. However, the inclined reflecting surface 194 is not limited to these, and even if such a special reflecting member is not provided. It is assumed that the required reflection function is satisfied by the difference in refractive index between air and acrylic resin.
[0226]
Here, the inclined reflecting surface 194 has an average pitch of 200 μm, an average height of 10 μm, and an average inclination angle of 41 °. The height of the inclined reflecting surface 194 is continuously changed so as to be lower near the light source 190 and higher at a position far from the light source 190, or the pitch or the inclined angle of the inclined reflecting surface 194 is a distance from the light source 190. Thus, the uniformity of the light emitted from the light guide 193 may be improved by changing the thickness continuously or by reducing the thickness of the light guide 193 as the distance from the light source 190 increases.
[0227]
The shape of the light guide 193 is not limited to this shape as long as the polarization state of light incident on the light guide 193 from the liquid crystal display panel 200 side is substantially maintained.
[0228]
The polarization maintaining reflection sheet 192 is formed by forming a reflection surface that maintains the polarization state on a substrate such as a glass plate, a resin plate, or a resin film. The light that has returned from the liquid crystal display panel 200 side to the illumination device 100 is again transmitted. It has a function of reflecting toward the liquid crystal display panel 200 side while maintaining the polarization state. The reflecting surface that maintains the polarization state described here is a reflecting surface in which linearly polarized light is reflected as it is with the same linearly polarized light, and circularly polarized light is reflected as circularly polarized light whose rotation direction is opposite, at least for vertically incident light. That is. Specifically, the reflective surface is a mirror-reflecting surface formed by applying a thin metal film such as Al or Ag to the base material as a reflecting surface, or a dielectric multilayer film configured to obtain a high reflectance with respect to the wavelength band of the light source light. Is used.
[0229]
The polarization maintaining diffusion unit 191 is for uniformizing the emission angle distribution of the light emitted from the light guide 193 and the luminance distribution in the plane, and further substantially maintains the polarization state of the light passing therethrough. is there. The polarization maintaining and diffusing unit 191 includes a plurality of spherical transparent beads arranged on a surface of an optically isotropic transparent substrate and fixed with a transparent resin, or an optically isotropic transparent substrate. Or a light control glass (LCG) described in SPIE, Vol. 1536, Optical Materials Technology for Energy Efficiency and Solar Energy Conversion X (1991), pp138-148, or the like can be used.
[0230]
FIG. 30 is an explanatory view of the axis direction of each member of the present embodiment. As shown in the figure, when a TN liquid crystal display panel is used as the liquid crystal display panel 200, the transmission polarization axis of the linearly polarized light of the polarizing plate 209 is usually 45 ° or 135 ° in order to obtain the horizontal symmetry of the viewing angle characteristics. (45 ° in this embodiment). The liquid crystal alignment axis on the transparent substrate 202 side and the liquid crystal alignment axis on the transparent substrate 201 side are 45 ° and 135 °, respectively, the transmission polarization axis of the linearly polarized light of the reflective polarization selection member 300 is 135 °, and the transmission polarization axis variable unit 400. The alignment directions of the major axis of the liquid crystal molecules on the transparent substrate 402 side and the transparent substrate 401 side are 135 ° and 45 °, respectively, and the transmission polarization axis of the linearly polarized light of the absorption polarization selection member 500 is 45 °.
[0231]
Next, the operation of this embodiment will be described. Light emitted from the light source 190 enters the light guide 193 and propagates through the light guide 193 while repeating total reflection. Of the light propagating through the light guide 193, the light reaching the inclined inclined surface 194 changes its traveling direction and is emitted from the surface side of the light guide 193. The light emitted from the light guide 193 is applied to the liquid crystal display element 200 after the polarization maintaining and diffusing unit 191 makes the emission angle distribution and the luminance distribution in the plane uniform.
[0232]
Of the light irradiated to the liquid crystal display panel 200, the linearly polarized light that has passed through the polarizing plate 209 passes through the liquid crystal layer 207 and enters the reflective polarization selection member 300. At this time, the light passes through the liquid crystal layer 208. The polarization state of light can be changed by a voltage applied to the liquid crystal layer 207. For this reason, a voltage corresponding to the image information transmitted from the image information generation unit is applied to the transparent electrodes 203 and 205 on the transparent substrates 202 and 201, and an electric field is applied to the liquid crystal layer 207, whereby light passing through the liquid crystal layer 207 is obtained. By changing the polarization state and controlling the amount of light transmitted through the reflective polarization selection member 300, an optical image made of linearly polarized light can be formed. That is, the reflection-type polarization selection member 300 of this embodiment also functions as the absorption-type polarization selection member (polarizing plate) 208 disposed on the viewer side of the liquid crystal display panel 200 in Embodiment 1.
[0233]
The image light transmitted through the reflective polarization selection member 300 enters the transmission polarization axis variable unit 400. When the display device is in an image display state, the transmission polarization axis variable unit 400 is in a state where no voltage is applied to the liquid crystal layer 407 constituting the display device, that is, in an off state.
[0234]
Here, if the linearly polarized light component transmitted through the reflective polarization selection member 300 is the first linearly polarized light component, and the linearly polarized light component whose polarization axis is orthogonal to the second linearly polarized light component, the transmitted polarization axis variable unit 400 is used. The image light passing through the light changes from the first linearly polarized light to the second linearly polarized light. The image light transmitted through the transmission polarization axis variable unit 400 is incident on the absorption polarization selection member 500. Since the absorption polarization selection member 500 absorbs the first linear polarization component and transmits the second linear polarization component, the image light 3001 changed to the second linear polarization light by the transmission polarization axis variable unit 400 is the absorption type. The light passes through the polarization selection member 500 and is observed by an observer.
[0235]
When the display device is in a mirror state, the transmission polarization axis variable unit 400 applies an electric field to the liquid crystal layer 407 constituting the display device to turn it on. At this time, since the present display device does not have the absorptive polarization selection member (polarizing plate) 208 provided as the absorptive polarization selection member in the above embodiment, when the illumination device 100 is turned on, the image light is directed to the observer side. Since it leaks, the contrast ratio of the reflected image is lowered, and an easy-to-see mirror cannot be realized. Accordingly, the lighting device 100 is turned off when in the mirror state. In the case of the present embodiment, the LED can be turned on and off at high speed by using the LED as the light source 190 of the illumination device 100, so that the mirror state and the image display state can be switched at high speeds without causing the observer to feel stress.
[0236]
On the other hand, when external light traveling from the viewer side toward the display device passes through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed, and only the second linearly polarized light component is transmitted to change the transmission polarization axis. It enters the part 400. The external light that has entered the transmission polarization axis variable unit 400 passes through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and reaches the reflective polarization selection member 300. Since the reflective polarization selection member 300 transmits the first linearly polarized light component and the second linearly polarized light component is specularly reflected, the external light 3002 is reflected by the reflective polarization selection member 300. The external light 3002 reflected by the reflective polarization selection member 300 is transmitted through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and is further transmitted through the absorption polarization selection member 500 to the observer. Head to.
[0237]
Therefore, since the display device of this embodiment turns off the illumination device in the mirror state, image light does not reach the observer, and ideally half of the unpolarized light out of the external light is reflected polarized light. Since it reflects by the selection member 300 and goes to the observer side, it functions as a bright mirror.
[0238]
In addition, this embodiment has the following specific effects.
[0239]
FIG. 31 is a diagram for explaining an effect peculiar to the present embodiment. Here, if the linearly polarized light component transmitted through the reflective polarization selection member 300 is a first linearly polarized light component, and the linearly polarized light component whose polarization axis is orthogonal to the second linearly polarized light component, the polarizing plate 209 is Of the linearly polarized light component.
[0240]
In the present display device, as described above, the second linearly polarized light (perpendicular to the paper surface in the drawing) transmitted through the polarizing plate 209 out of the light emitted from the lighting device 100 to the liquid crystal display panel 200 passes through the liquid crystal layer 207. Then, the light enters the reflective polarization selection member 300. At this time, the polarization state of the light transmitted through the liquid crystal layer 207 is modulated corresponding to the image information, and the light 3100 passing through the bright display region changes from the second linearly polarized light to the first linearly polarized light and is reflected. The light passes through the mold polarization selection member 300 and travels toward the observer.
[0241]
On the other hand, since the light 3101 passing through the dark display region is incident on the reflective polarization selection member 300 as the second linearly polarized light, it is reflected by the reflective polarization selection member 300 and does not reach the observer. The light 3101 reflected by the reflective polarization selection member 300 passes through the liquid crystal layer 207 and the polarizing plate 209 again as the second linearly polarized light and returns to the illumination device 100. At this time, the polarization maintaining diffusion unit, the light guide, and the polarization maintaining reflection sheet 192 that configure the illumination device 100 transmit or reflect while maintaining the polarization state of the light returning from the liquid crystal display element 200 side. For this reason, the light 3101 that is reflected by the illumination device 100 and travels toward the liquid crystal display panel 200 is substantially second linearly polarized light, and therefore is incident on the liquid crystal layer 207 with almost no absorption by the polarizing plate 209. Of the light 3101 incident on the liquid crystal layer 207, the light incident on the bright display region is changed from the second linearly polarized light to the first linearly polarized light and is transmitted through the reflective polarization selection member 300 for observation. It can be effectively used as image light.
[0242]
That is, the light incident on the dark display region is not reflected as image light because it is initially reflected by the reflective polarization selection member 300. However, the light reflected by the reflective polarization selection member 300 is directed to the illumination device 100, is reflected with the polarization state being substantially maintained in the illumination device 100, and travels toward the liquid crystal display panel 200 again. For this reason, light is reused in a state without a large loss, and the brightness of the bright display area is improved.
[0243]
In general, the light transmittance of the color filter is as low as about 25%. However, since the color filter is not used in this embodiment, the light is reused more efficiently.
[0244]
Here, in general, in a liquid crystal display panel, the brightness of white display does not change between when the entire screen is displayed in white and when a portion is displayed in white. On the other hand, CRT (Cathode Ray Tube) is said to be able to brighten the white display by about four times when displaying 15% of the screen in white, compared to displaying white on the entire screen. This appears as a difference in image quality that, for example, when a partially bright image such as sunlight is displayed, the CRT can provide a more powerful image than the liquid crystal display panel.
[0245]
In the display device of this embodiment, since the brightness of the bright display area can be improved by reusing light incident on the dark display area, a part of the screen is displayed in white compared to the case where the entire screen is displayed in white. The white display can be brightened when doing so. Therefore, a powerful image close to a CRT can be obtained.
[0246]
Further, when the present display device is used as a display unit of a portable device such as a mobile phone, the following effects can be obtained. This display device functions as a color display device by the field sequential color display method when the lighting device is turned on, but when the lighting device is turned off, it functions as a reflective liquid crystal display panel for bright monochrome display because there is no color filter. Can be made. Here, in the case of color display, it is necessary to display at least three sub-frames of red, green, and blue in order to display one frame, but in the case of monochrome display, it is not necessary to provide sub-frames, so that driving is performed. The frequency can be reduced to 1/3 or less. If the drive frequency can be lowered to one third or less, the power consumption can be greatly reduced. Therefore, if the drive frequency switching unit is provided so that the drive frequency can be changed between the color display state and the monochrome display state. The power consumption in the monochrome display state can be greatly reduced.
[0247]
In other words, when this display device is used as a display unit of a portable device, the lighting device is turned on when the device is in use, and it is powerful by setting it in a color display state, and a bright and high-quality image can be obtained. When the apparatus is on standby, the lighting device is turned off, the driving frequency is lowered, and the monochrome display state is achieved, so that the power consumption can be extremely reduced. For this reason, the use time by the battery of a portable apparatus can be lengthened, for example, the standby time of a mobile telephone can be lengthened.
[0248]
Furthermore, as described above, these effects can be switched between the image display state and the mirror state without degrading the performance of each other. Further, in this embodiment, a metal linear pattern is formed on a transparent substrate on the viewer side of the liquid crystal display panel, and a part of each pattern is electrically connected, so that the metal linear pattern is transparent. It is good also as a structure which combines the function of an electrode and a reflective polarization | polarized-light selection member.
[0249]
(Example 6)
Other embodiments of the present invention will be described below with reference to the drawings.
[0250]
A display device with a switching function to the mirror state according to the sixth embodiment of the present invention will be described with reference to FIG. This display device uses the reflective liquid crystal panel 3000 as the image display unit 1000 in the above-described first embodiment, and the same members as those in the above-described embodiment are denoted by the same reference numerals and detailed description thereof is omitted.
[0251]
The display device of Example 6 includes a reflective liquid crystal element 3000. The reflective liquid crystal element includes a transparent substrate 3030, a reflective substrate 3100 having a reflective portion, and these two substrates via spacers such as beads. A liquid crystal layer 3130 sealed in a space formed by bonding and sealing with a frame-shaped sealing material is provided. In addition, a retardation plate 3020, a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and an absorption polarization selection member 500 are disposed on the transparent substrate 3030 in an overlapping manner.
[0252]
As the reflective substrate 3100, a flat insulating substrate such as glass or a polymer film is used, and here, a glass substrate having a thickness of 0.7 mm is used. The reflective substrate 3100 includes a scanning electrode and a signal electrode, a switching element 3110 made of, for example, a TFT (Thin Film Transistor) provided at an intersection thereof, an insulating layer 3090 formed thereon, and an insulating layer. And pixel electrodes 3070 subdivided in a matrix shape electrically connected to the switching elements through through holes 3120 opened in the insulating layer 3090.
[0253]
The pixel electrode 3070 is made of a metal having high reflectivity such as aluminum or silver, and functions as a diffuse reflection reflecting portion due to a fine concave or convex shape formed on the insulating layer 3090. An alignment film 3060 made of a polyimide-based polymer is formed on the entire surface of the pixel electrode 3070, and the surface thereof is subjected to surface treatment by a rubbing method or the like.
[0254]
As the transparent substrate 3030, an optically isotropic and flat transparent insulating substrate such as glass or a polymer film can be used. Here, a glass substrate having a thickness of 0.7 mm was used. A color filter 3040 is formed on the transparent substrate 3030 at a position corresponding to the pixel electrode 3070 of the reflective substrate 3100. The color filter 3040 is obtained by alternately repeating three types of color filters having transmission spectra corresponding to the three primary colors of red, green, and blue, respectively, and arranging them at positions corresponding to the pixel electrodes 3070.
[0255]
Further, a black matrix may be formed at a position corresponding to between the pixels of the color filter 3040 so as to suppress leakage light from between the pixels. A transparent electrode 3050 made of ITO is formed on the entire surface of the color filter 3040 through an overcoat layer (not shown), and an alignment film 3210 made of polyimide polymer is formed on the entire upper layer of the transparent electrode 3050. Then, the surface is subjected to a surface treatment by a rubbing method or the like.
[0256]
The transparent substrate 3030 and the reflective substrate 3100 are bonded so that the transparent electrode 3050 formation surface and the reflective electrode 3070 formation surface face each other. At this time, bead spacers are distributed between the two substrates, and the space corresponding to the display surface of both the substrates is sealed with a frame-shaped sealing material to form a space having a certain gap.
[0257]
In a gap between the substrates 3030 and 3100, a liquid crystal composition in which a small amount (0.1 to 0.2%) of a chiral agent is added to nematic liquid crystal having positive dielectric anisotropy is sealed and sealed to form a liquid crystal layer 3130. Configured. Δnd of the liquid crystal layer 3130 was set to 0.365 μm. The direction of the major axis of the liquid crystal molecules of the liquid crystal layer 3130 is defined by the surface treatment (alignment treatment) performed on the transparent substrate 3030, the alignment film 3210 formed on the reflective substrate 3100, and the alignment film 3060. It is in a state of being twisted by a predetermined angle continuously between the substrates.
[0258]
A retardation plate 3020 is laminated on the transparent substrate 3030. As the retardation plate 3020, for example, a uniaxially stretched polymer film such as polycarbonate, polysulfone, or polyvinyl alcohol can be used. Here, a phase difference plate made of polycarbonate having a Δnd of 0.18 μm is used as the phase difference plate 3020.
[0259]
The transparent substrate 3030, the retardation plate 3020, the reflective polarization selection member 300, the transmission polarization axis variable unit 400, and the absorption polarization selection member 500 were bonded to each other by an acrylic adhesive so as to be optically coupled.
[0260]
FIG. 33 is a diagram showing the directions of the axes of the members of the display device when viewed from the observer side. The angle of each axis is indicated by the counterclockwise angle from the position of the image display surface at 3 o'clock in the horizontal direction. As shown in FIG. 33, the display device has a liquid crystal alignment axis on the reflective substrate 3100 side of 295 °, an azimuth angle of the liquid crystal alignment axis on the transparent substrate 3030 side of 65 °, a slow axis of the retardation film 3020 of 135 °, and a reflective type. The transmission axis of the linearly polarized light of the polarization selection member 300 is 30 °, the liquid crystal alignment axis of the transparent substrate 402 side is 30 °, the liquid crystal alignment axis of the transparent substrate 401 side is 120 °, and the linearly polarized light of the absorption polarization selection member 500 is transmitted. The polarization axis was 120 °.
[0261]
Next, the operation of the display device will be described with reference to the drawings. In the present embodiment, as in the first embodiment, the linearly polarized light component transmitted through the reflective polarization selection member 300 is defined as the first linearly polarized light component, and the linearly polarized light component whose polarization axis is orthogonal to the second linearly polarized light component. Of the linearly polarized light component.
[0262]
FIG. 34 shows a case where the display device is in a mirror state. In this case, the external light 3002 from the observer side toward the display device is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized component is absorbed, and only the second linearly polarized component is present. Is transmitted and enters the transmission polarization axis variable unit 400. The external light 3002 incident on the transmission polarization axis variable unit 400 is transmitted through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and reaches the reflection type polarization selection member 300. Since the reflective polarization selection member 300 transmits the first linearly polarized light component and the second linearly polarized light component is specularly reflected, the external light 3002 is reflected by the reflective polarization selection member 300. The external light 3002 reflected by the reflective polarization selection member 300 is transmitted through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and is further transmitted through the absorption polarization selection member 500 to the observer. Head to.
[0263]
That is, when the display device is in a mirror state, the external light 3002 does not reach the reflective liquid crystal element 3000, but is reflected by the reflective polarization selection member 300 and functions as a bright mirror toward the viewer.
[0264]
Note that when the display device is in a mirror state, the reflective liquid crystal element 3000 can be in a non-display state so that unnecessary power is not consumed.
[0265]
35 and 36 show a case where the display device is in an image display state. The image display state will be described with reference to FIG. In this case, the external light 3002 from the observer side (left side in the figure) toward the display device is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed and the second light Only the linearly polarized light component is transmitted. When the external light 3002 that has passed through the absorption-type polarization selection member 500 passes through the transmission polarization axis variable unit 400, it changes from the second linearly-polarized light to the first linearly-polarized light, and passes through the reflective-type polarization selection member 300. Is incident on the reflective liquid crystal element 3000. The first linearly polarized light incident on the reflective liquid crystal element 3000 passes through the phase difference plate 3020 and the liquid crystal layer 3130, is reflected by the pixel electrode 3070, passes through the liquid crystal layer 3130 and the phase difference plate 3020 again, and is reflected. The light enters the polarization selection member 300. At this time, the polarization state of the light transmitted through the liquid crystal layer 3130 varies depending on the voltage applied to the liquid crystal layer 3130.
[0266]
Here, the switching element 3110 is connected to the pixel electrode 3070 via the through-hole 3120, and a liquid crystal layer sandwiched between the transparent electrode 3050 and the pixel electrode 3070 by switching a voltage applied to the pixel electrode 3070. The voltage applied to 3130 can be controlled for each pixel. Therefore, a voltage corresponding to image information is applied to the transparent electrode 3050 and the pixel electrode 3070, and a predetermined voltage is applied to the liquid crystal layer 3130, thereby controlling the polarization state of light passing through the liquid crystal layer 3130, and reflecting type An optical image can be formed by controlling the amount of light transmitted through the polarization selection member 300.
[0267]
FIG. 35 shows the case of bright display. In the configuration of this embodiment, when no voltage is applied to the liquid crystal layer 3130, the light incident on the reflective liquid crystal element 3000 is reflected as the first linearly polarized light and is transmitted through the reflective polarization selection member 300 again. Then, the light enters the transmission polarization axis variable unit 400. When the light that has entered the transmission polarization axis variable unit 400 passes through the light, it changes from the first linearly polarized light to the second linearly polarized light, passes through the absorption-type polarization selection member 500, and becomes brighter toward the observation side. Display.
[0268]
FIG. 36 shows the case of dark display. In the configuration of this embodiment, when a predetermined voltage is applied to the liquid crystal layer 3130, the first linearly polarized light incident on the reflective liquid crystal element 3000 is reflected by the reflective liquid crystal element 3000 and is emitted when the second linear line is emitted. It becomes polarized light and enters the reflective polarization selection member 300 again. The second linearly polarized light re-entering the reflective polarization selection member 300 is reflected by the reflective polarization selection member 300 and is incident on the reflective liquid crystal element 3000 again. The second linearly polarized light incident on the reflective liquid crystal element 3000 is reflected by the reflective liquid crystal element 3000 and becomes the first linearly polarized light when emitted.
[0269]
However, at this time, three types of color filters 3040 having different transmission spectra corresponding to the three primary colors of red, green, and blue are alternately and repeatedly formed on the transparent substrate 3030 of the reflective liquid crystal element 3000. Therefore, for example, as shown in the drawing, if light that first enters the reflective liquid crystal element 3000 enters and transmits the green color filter 3040G and enters the blue color filter 3040B in the second incidence, Light is almost absorbed and dark display is obtained. Further, even if the light incident on the reflective liquid crystal element 3000 passes through the color filter of the same color, a dark display can be obtained because the light passes through the color filter a total of four times in the forward pass. That is, in the configuration of this embodiment, a color filter is used as a member for improving the darkness of dark display.
[0270]
In order to realize a sufficiently dark dark display, it is desirable to pass through color filters of different colors when passing through the color filters four times. For this reason, it is desirable to arrange the color filters in a delta arrangement instead of a stripe form so that the colors of the adjacent color filters are different as much as possible in the vertical and horizontal directions.
[0271]
Further, the thicker the transparent substrate 3030 of the reflective liquid crystal element 3000, the light reflected by the reflective polarization selection member 300 passes through different positions of the reflective liquid crystal element 3000 and passes through different color filters. Therefore, it is desirable to make the transparent substrate 3030 as thick as possible within a practical range.
[0272]
As described above, according to the display device of the sixth embodiment, the reflective polarization selection member 300 is effectively transparent and controlled as a mirror by controlling the polarization state by the transmission polarization axis variable unit 400. Can be switched to. Therefore, in the image display state, a bright image can be obtained by effectively setting the reflective polarization selection member 300 in a transparent state. Furthermore, even in an environment where the surroundings are bright, there is no image quality degradation such as reflection as in the case of using a half mirror, a reduction in contrast ratio, and a reduction in brightness of image light. That is, switching between the image display state and the mirror state can be realized without degrading the performance of each other.
[0273]
By the way, in the present embodiment, the case where the reflective liquid crystal panel 3000 is not provided with a polarizing plate that functions as an absorption polarization selection member has been described. This is because it is important to reduce the number of members that absorb light as much as possible in order to improve the brightness of the image display state. In particular, an image is dark on a reflective liquid crystal display panel capable of color display, so the image may become darker due to a mirror function unit including an absorption polarization selection member, a transmission polarization axis variable unit, and a reflection polarization selection member. This is because it is in an unacceptable situation. Accordingly, a polarizing plate may be provided in the reflective liquid crystal element 3000 for applications such as outdoors where the usage frequency is high in places with strong external light.
[0274]
Furthermore, if the polarizing plate has a high transmittance close to 100% with respect to a predetermined linearly polarized light component, the polarizing plate transmits polarized light between the reflective liquid crystal element 3000, that is, between the reflective polarizing selection member 300 and the transparent substrate 3030. Even if the axis is aligned with the transmission polarization axis of the reflective polarization selection member, the brightness of the image is hardly reduced, which is desirable. In this case, generally, a polarizing plate having a high transmittance has a low degree of polarization, so that a reflective liquid crystal panel alone cannot display an image with a sufficient contrast ratio. However, if a polarizing plate having a high degree of polarization is used as the absorbing polarization selection member 500, There is no problem with display performance. On the contrary, when displaying an image, there is an advantage that a darker dark display can be realized and an image display with a high contrast ratio can be realized.
[0275]
In other words, when a reflective liquid crystal display panel having a reflection part built in the substrate is used as the image display member, a polarizing plate having a high degree of polarization is used as the absorption polarization selection member, and the reflective polarization selection member side of the image display member is used. When a polarizing plate having a low degree of polarization and a high transmittance is used for the absorbing polarization selection member to be arranged, both image brightness and a high contrast ratio are compatible.
[0276]
In this embodiment, the case where a reflective liquid crystal display panel is used has been described. However, an opening is provided in a part of a pixel electrode functioning as a reflective member so as to partially transmit, so that reflective display and transmissive display are performed. You may make it also use. In this case, a quarter retardation plate, a polarizing plate, and a lighting device may be disposed on the back side of the reflecting member. According to such a configuration, it is possible to display an image by turning on the lighting device even in a situation where the outside light is weak, such as at night or in a building.
[0277]
(Example 7)
Another embodiment of the present invention will be described with reference to the drawings.
[0278]
A display device with a switching function to the mirror state of the seventh embodiment will be described with reference to FIG. FIG. 38 is a schematic diagram showing an overview of a mobile phone using this display device. FIG. 38 (a) shows an image display state and FIG. 38 (b) shows a mirror state. FIG. 39 shows an example of a circuit configuration of a cellular phone using the display device shown in FIG.
[0279]
The mobile phone 810 of the seventh embodiment includes at least an antenna 811, a speaker 812, a button 814 such as a numeric keypad, a microphone 815, a mirror state / image display state changeover switch 813, and an image display unit 1000 and a mirror function unit 801 of the display device. It is comprised including.
[0280]
A cellular phone 810 according to the seventh embodiment includes a communication unit 10 that realizes a telephone function, an operation unit 20 that inputs an operation, and a display unit 30 according to the present invention that can switch between an information display state and a mirror state. The communication unit 10 is connected to the antenna 811 to perform transmission / reception processing of a communication signal, and performs input / output of audio information through the microphone 815 and the speaker 812 and transmits the audio information and the transmission / reception signal. A signal processing unit 822 that performs signal conversion processing and a communication control unit 823 that controls transmission / reception operations in accordance with input operation instructions are provided. The operation unit 20 includes a numeric keypad / button 814 for performing various operation inputs, and a changeover switch 813 for switching between an information display state and a mirror state.
[0281]
The display unit 30 includes an image display unit 1000 that includes the lighting device 836 and displays information, a display control unit 831 that receives a control instruction from the communication unit 10 or the operation unit 20 and performs operation control of the display unit, and display control. A drive circuit unit 832 that drives the image display unit 1000 in accordance with a control signal from the unit 831; a mirror function unit 801 that is superimposed on the image display unit 1000 and selectively realizes a mirror state and a transmission state; An applied voltage generator 834 that generates at least an applied voltage to the transmission polarization axis variable unit 400 of the unit 801, and an applied voltage generator 834 that switches the state of the mirror function unit 801 in accordance with an instruction from the changeover switch 813 or a communication state. A mirror control unit 833 that controls the lighting, and a lighting switch 835 that turns on and off the lighting device in accordance with control signals from the display control unit 831 and the mirror control unit 833. .
[0282]
In this display device, as shown in FIG. 37, the area of the mirror function unit 801 including the reflective polarization selection member 300, the transmission polarization axis variable unit 400, and the absorption polarization selection member 500 is represented by the image display region 1001 of the image display unit 1000. The area other than this is basically the same as the first embodiment and has the same configuration and function as those of the first embodiment.
[0283]
The reflective polarization selection member 300 of the mirror function unit 801 is fixed to a substrate constituting the transmission polarization axis variable unit 400 by a transparent adhesive material. In addition, the reflective polarization selection member 300 is in contact with the image display unit 1000 halfway and interference fringes and the like are not generated, so that a frame 810F of the mobile phone is provided between the mirror function unit 801 and the image display unit 1000. A certain space 801S is provided using the formed convex portion 801a as a spacer.
[0284]
Here, as described above, when the display device is in a mirror state, the display device does not display information such as data on the display device, but it is defined that the main application is that the observer displays his / her face and observes it. Then, as described above, the size of the mirror is desirably 58.6 mm in height and 39.1 mm in width or more. However, the size of the image display member cannot be increased because there is a problem that the power consumption increases when the image display portion is enlarged. On the other hand, the mirror function unit does not have a problem by increasing its area. Therefore, in the seventh embodiment, the area of the mirror function unit is set as large as possible regardless of the area of the image display region 1001.
[0285]
Further, the mirror function unit 801 of the present display device can effectively switch between the transparent state and the mirror state by controlling the polarization state by the transmission polarization axis variable unit 400. Therefore, even if the large-area mirror function unit 801 is arranged on a design such as a logo mark, if it is effectively transparent, it will not affect the groundwork, thus depriving the design freedom of the equipment. I will not.
[0286]
Next, the operation of the cellular phone 810 of this embodiment will be described with reference to FIG.
[0287]
As shown in FIG. 38 (a), when displaying an image even when the mobile phone is in use or in standby, the mirror function unit 801 is effectively in a transparent state, and a bright image display is obtained. In addition, the logo mark and design around the image display section are also visible. On the other hand, in the mirror state, as shown in FIG. 38B, a mirror surface larger than the image display unit appears and a practical mirror can be obtained.
[0288]
Note that the display device according to the seventh embodiment is configured so that the mirror state and the image display state can be performed with a single touch of the changeover switch 813, and thus the operability is high. The changeover switch 813 is configured to switch between a case where an AC voltage of about ± 3 V to ± 5 V is applied to a pair of electrodes sandwiching the liquid crystal layer of the transmission polarization axis variable unit 400 and a state where the pair of electrodes are short-circuited. . Further, in conjunction with the changeover switch 813, the power consumption is reduced by setting the image display unit 1000 to the non-display state and turning off the lighting device in the mirror state.
[0289]
In addition, since the switching from the mirror state to the image display state is automatically switched by an incoming call, the incoming call information can be viewed without a switch operation, which further improves user convenience.
[0290]
Note that the mirror state and the image display state are switched at a high speed of several tens of milliseconds when a TN liquid crystal element is used as the transmission polarization axis variable unit 400, so that there is no inconvenience to the user.
[0291]
In this embodiment, the area of the mirror function unit 801 is larger than the area of the image display region 1001. However, in the present invention, the area of the mirror function unit 801 or the region where the mirror state can be realized and the image display region 1001 or the transmission region. The ratio of the area of the mold / reflective image display member is not limited to this example. Of course, both areas may be substantially the same as in the above embodiments, or the area of the mirror function part may be made smaller, or the mirror function part may be overlaid on the image display part except for a specific area. Is also possible. For example, it is possible to adopt a configuration in which only the display portion of the mark is not covered with the mirror function section so that only the mark indicating whether the mobile phone is in a communicable state can always be checked.
[0292]
Furthermore, in this embodiment, the case where the entire mirror function unit is in the mirror state has been described. For example, the mirror area of the mirror function unit is divided into a plurality of parts, and the mirror state and the image display state are switched for each divided region. It can be set as the structure which performs. More specifically, for example, voltage application to the transmission polarization axis variable unit or the variable absorption polarization selection member is performed for each divided region, or pixel electrodes are arranged in a matrix to form an arbitrary picture or character in a mirror state. Can be displayed.
[0293]
(Example 8)
Another embodiment of the present invention will be described with reference to the drawings.
[0294]
Embodiment 8 of the present invention will be described with reference to FIGS. 40, 41, and 42. FIG. In the eighth embodiment, the same parts as those in the seventh embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0295]
The configuration of the eighth embodiment is a detachable mirror function unit that allows a user to add a mirror function to an existing mobile phone. As shown in FIG. 41, the detachable mirror function unit 801 includes a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and an absorption polarization selection member 500, which are transparent to each other. The material is bonded and fixed. Further, a transparent protective member 500P made of a film or a thin acrylic plate is bonded to the surface of the absorption polarization selection member 500 with a transparent adhesive material. A frame-like spacer 843 having a sponge shape and elasticity is provided at the peripheral edge of the reflective polarization selection member 300, and a double-faced tape 844 is provided on the surface of the spacer 843 as necessary. The spacer 843 is arranged so that the reflective polarization selection member 300 maintains a certain space without contacting the other members when the mirror function unit is attached to a device such as a mobile phone. This prevents the reflection type polarization selection member 300 and other members from coming into contact with each other to generate interference fringes.
[0296]
The transmission polarization axis variable unit 400 is connected to the mirror function driving unit 840 via a wiring connected to a transparent electrode formed in the shape of a transparent substrate constituting the transmission polarization axis variable unit 400.
[0297]
As shown in FIG. 42, the mirror function drive unit 840 includes a power source 845 formed of a small battery, and a drive circuit 847 that generates a voltage for driving the transmission polarization axis variable unit 400 by power supply from the changeover switch 846 and the power source 845. Then, by operating the changeover switch 846, the transmission polarization axis variable section 400 is driven to switch the mirror function section between the mirror state and the transparent state.
[0298]
When the mirror function unit 801 is attached to the mobile phone 810, the wiring between the mirror function unit 801 and the mirror function driving unit 840 is attached via the strap attaching unit 841 of the mobile phone, and the wiring 842 and the mirror function driving unit. It can be configured to be attached as if 840 is a strap. In this case, even if the mirror function driving unit 840 is accidentally pulled, the force is stopped by the strap attaching portion 841 of the mobile phone, and there is an advantage that the mirror function unit is not directly applied.
[0299]
Example 9
A display apparatus according to Embodiment 9 of the present invention will be described with reference to FIG.
[0300]
The display device of Example 9 in FIG. 43 uses an organic electroluminescence (EL) display panel 900 as an image display unit that emits image light, and the same reference numerals are used for the same members as in Example 1 above. Detailed explanation is omitted.
[0301]
The display device includes an organic EL display panel 900 that emits first linearly polarized image light, a reflective polarization selection member 300, a transmission polarization axis variable unit 400, and an absorption polarization selection member 500. . The organic EL display panel 900 transmits the first linearly polarized light component on the side facing the reflective polarization selection member 300 and absorbs the second linearly polarized light component whose polarization axis is orthogonal to the absorption polarization selection member 208. And a phase difference plate 901 are arranged.
[0302]
A quarter wave plate may be used as the retardation plate 901. For example, a polymer film such as uniaxially stretched polycarbonate, polysulfone, or polyvinyl alcohol may be used. In general, due to the wavelength dependence (hereinafter referred to as wavelength dispersion) of the refractive index of the material constituting the quarter-wave plate, one type of retardation plate functions as a quarter-wave plate for the entire visible wavelength range. Although it is difficult to configure a plate, it is configured to function as a quarter-wave plate in a wide wavelength range by bonding at least two types of retardation plates with different wavelength dispersion so that their optical axes are orthogonal to each other. Things can be used.
[0303]
The organic EL display panel 900 is a self-luminous display device that emits light by converting electric energy into light energy by injecting a current into a light emitting layer made of an organic thin film, and a transparent electrode 903 made of ITO on a transparent substrate 902, It has a structure in which a hole transport layer 904, a light emitting layer 907, an electron transport layer 906, and a reflective metal electrode 905 composed of Al or the like are sequentially stacked. These laminated films are sealed with a sealing agent 908 in a state where oxygen and moisture are removed between the transparent substrate 902 and the sealing member 909 in order to suppress deterioration.
[0304]
In the organic EL display panel, when a DC voltage is applied between the transparent electrode 903 serving as the anode and the reflective metal electrode 905 serving as the cathode, holes injected from the transparent electrode 903 pass through the hole transport layer 904 and When electrons injected from the cathode (reflective metal electrode) 905 reach the light-emitting layer 907 via the electron transport layer, electron-hole recombination occurs, and light having a predetermined wavelength is generated therefrom. It is considered. The light emitted from the light emitting layer 907 is generally not directional and isotropically emitted in all directions. Therefore, in order to efficiently use the light directed toward the metal electrode 905 as display light, the metal electrode has a reflectance. It is desirable to use a high electrode material.
[0305]
The configuration of the organic EL display panel 900 is not limited to the above configuration. That is, the organic EL display panel according to the present invention can use a self-luminous display device including at least a light emitting layer and a reflective member disposed on the back surface of the light emitting layer.
[0306]
Next, the operation of the display device according to the ninth embodiment will be described with reference to FIG. In FIG. 43, the right side shows the image display state, and the left side shows the mirror state.
[0307]
When the display device is in an image display state, the transmission polarization axis variable unit 400 is in a state in which no voltage is applied to the liquid crystal layer 407 constituting the display device, that is, in an off state. In the image display state, the light emitted from the light emitting layer is emitted from the transparent substrate 902 directly or after being reflected by the metal electrode 905 on the back surface.
[0308]
When the image light 3201 emitted from the transparent substrate 902 passes through the retardation plate 901 and passes through the absorption polarization selection member 208, the first linearly polarized light component is transmitted, and the second straight line whose polarization axis is orthogonal to this. The polarization component is absorbed. The image light 3201 transmitted through the absorption-type polarization selection member 208 is also transmitted through the reflection-type polarization selection member 300 and is incident on the transmission polarization axis variable unit 400. In this case, the image light 3201 passing through the transmission polarization axis variable unit 400 changes from the first linearly polarized light to the second linearly polarized light. The image light 3201 transmitted through the transmission polarization axis variable unit 400 is incident on the absorption polarization selection member 500. Since the absorption-type polarization selection member 500 absorbs the first linearly polarized light component and transmits the second linearly polarized light component, the image light 3201 changed to the second linearly polarized light by the transmission polarization axis variable unit 400 is the absorption type. The light passes through the polarization selection member 500 and is observed by the observer 2000.
[0309]
On the other hand, the external light 3202 incident on the display device from the viewer 2000 side is non-polarized light, but when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed and the second linearly polarized light component. Only transparent. When the external light 3202 that has passed through the absorption-type polarization selection member 500 passes through the transmission polarization axis variable unit 400, the external light 3202 changes from the second linearly-polarized light to the first linearly-polarized light and passes through the reflective-type polarization selection member 300. Then, the light enters the organic EL display panel 900.
[0310]
The external light 3202 incident on the organic EL display panel 900 passes through the absorption-type polarization selection member 208 and passes through the phase difference plate 901, and thus receives circularly polarized light (here, for example, clockwise circularly polarized light). It becomes. When the external light 3202 transmitted through the phase difference plate 901 is reflected by the metal electrode 905, it becomes circularly polarized light (counterclockwise circularly polarized light) whose phase is shifted by π and whose rotation direction is reversed. When the external light 3202 reflected by the metal electrode 905 is transmitted again through the phase difference plate 901, it receives the action, and this time becomes second linearly polarized light and is absorbed by the absorption type polarization selection member 208, so Dont return.
[0311]
Therefore, in the image display state, the image light 3201 emitted from the organic EL display panel 900 travels to the viewer with almost no loss, so that a bright image can be obtained. In addition, the external light 3202 incident on the display device from the surroundings is not reflected by the reflective polarization selection member 300 that functions as a mirror in the mirror state, and the light reflected by the metal electrode 905 of the organic EL display panel 900 is not reflected. Since it is absorbed by the absorption type polarization selection member 208, it is hardly visually recognized by the observer 2000. That is, it is possible to realize an image display with a high contrast ratio in which unnecessary reflection of external light is suppressed.
[0312]
On the other hand, when the display device is in a mirror state, the transmission polarization axis varying unit 400 applies an electric field to the liquid crystal layer 407 constituting the display device to turn it on. In the mirror state, the external light 3203 from the observer 2000 toward the display device is non-polarized light. However, when passing through the absorption-type polarization selection member 500, the first linearly polarized light component is absorbed and the second linearly polarized light is absorbed. Only the component is transmitted and enters the transmission polarization axis variable unit 400. At this time, the external light 3203 incident on the transmission polarization axis variable unit 400 passes through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and reaches the reflection type polarization selection member 300. In the reflective polarization selection member 300, the first linear polarization component is transmitted and the second linear polarization component is specularly reflected, so that the external light 3203 is reflected by the reflection polarization selection member 300. The external light 3203 reflected by the reflective polarization selection member 300 passes through the transmission polarization axis variable unit 400 as the second linearly polarized light without changing the polarization axis, and further passes through the polarization selection member 500 and travels toward the observer. Therefore, the mirror state is realized.
[0313]
At this time, the display area of the organic EL display panel 900 corresponding to the area in the mirror state is desirably in a non-light-emitting state in conjunction with the operation of the mirror function. By this operation, light leakage from the back side of the reflective polarization selection member 300 can be completely eliminated, so that a high-quality mirror that reflects a reflected image with a high contrast ratio can be realized, and the amount of emitted light can be reduced. The power consumption of the display device is reduced by the amount of suppression.
[0314]
However, it is not always necessary to turn off the light, and even when image light is emitted from the organic EL display panel 900, the image light emitted from the organic EL display panel 900 is transmitted through the absorption polarization selection member 208. Since the first linearly polarized light is transmitted through the reflective polarization selection member 300, the first linearly polarized light is transmitted through the transmission polarization axis variable unit 400 without changing the polarization axis, thereby absorbing the polarized light. Since it is absorbed by the selection member 500 and hardly observed by the observer 2000, a mirror that reflects a reflected image with a high contrast ratio can be realized.
[0315]
The characteristics of the polarizing plate functioning as the absorption polarization selection member 208 or the absorption polarization selection member 500 are directly related to the image quality in the image display state and the visibility of the mirror in the mirror state. For this reason, as in the first embodiment, in order to improve the luminance while maintaining a sufficient contrast ratio in the image display state, either the absorption polarization selection member 208 or the absorption polarization selection member 500 is used. It is effective to use a polarizing plate with a high degree of polarization and a polarizing plate with a low degree of polarization on the other side.
[0316]
As in each of the embodiments described above, according to the display device of the present invention, the reflective polarization selection member that functions as a mirror can be arbitrarily switched between a transparent state and a state that functions as a mirror. There is an effect that switching between the image display state and the mirror state can be realized without degrading the performance of each other. In other words, a bright image with almost no loss of image light can be obtained in the image display state, and even in a bright environment, there is no deterioration in image quality due to external light, such as reflection and a corresponding decrease in contrast ratio. There is an effect that an image can be obtained.
[0317]
On the other hand, in the mirror state, a bright mirror can be realized because the external light is efficiently reflected. Further, since leakage of image light is suppressed, there is an effect that a mirror that displays a reflected image with a high contrast ratio can be realized. Therefore, in the mirror state, it is possible to obtain an easy-to-see reflection image suitable for a person to observe his / her face and figure.
[0318]
【The invention's effect】
As described above, according to the present invention, it is possible to switch between a state in which a high-quality image is displayed and a mirror state in which an easy-to-see reflected image suitable for observing a person's face and figure is obtained. Device can be provided.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram for explaining the basic configuration and operation of a display device with a function of switching to a mirror state according to a first embodiment of the present invention.
FIG. 2 is an explanatory diagram for explaining the basic configuration and operation of a display device with a function of switching to a mirror state according to the first embodiment of the present invention.
FIG. 3 is a graph showing light leakage in a bright display area when the display device of FIGS. 1 and 2 is in a mirror state;
FIG. 4 is a graph showing light leakage in a dark display region when the display device of FIGS. 1 and 2 is in a mirror state.
FIG. 5 is an explanatory diagram for explaining the basic configuration and operation of a display device with a switching function to a mirror state according to a second embodiment of the present invention.
FIG. 6 is an explanatory diagram for explaining a basic configuration and an operation of a display device with a function of switching to a mirror state according to a second embodiment of the present invention.
FIG. 7 is a cross-sectional view showing a configuration of a display device according to Embodiment 1 of the present invention.
FIG. 8 is a cross-sectional view of each member constituting the display device according to the first embodiment of the present invention.
FIG. 9 is an explanatory diagram of the axial direction of each member constituting the display device according to the first embodiment of the present invention.
FIG. 10 is an explanatory diagram for explaining the operation of the display device according to the first embodiment of the invention.
FIG. 11 is an explanatory diagram for explaining the operation of the display device according to the first embodiment of the invention.
FIG. 12 is a graph showing an example of the relationship between the degree of polarization and transmittance of a general polarizing plate.
FIG. 13 is a graph showing the relationship between the degree of polarization of the absorptive polarization selection member 500 according to the display device of Example 1 of the present invention, the reflectance in the mirror state, and the reflectance of external light in the image display state. is there.
14 is a graph showing the relationship between the degree of polarization of the absorptive polarization selection member 208 according to the display apparatus of Example 1 of the present invention and the display luminance in the image display state. FIG.
FIG. 15 is a cross-sectional view showing a configuration of a display device according to a second embodiment of the present invention.
FIG. 16 is a cross-sectional view of each member constituting the display device according to the second embodiment of the present invention.
17 is a cross-sectional view showing an example of the configuration of a variable polarization selection member 600 of a display device according to Embodiment 2 of the present invention. FIG.
18 is a cross-sectional view showing an example of the configuration of a variable polarization selection member 600 of a display device according to Embodiment 2 of the present invention. FIG.
FIG. 19 is an explanatory diagram of the axial direction of each member constituting the display device according to the second embodiment of the present invention.
FIG. 20 is an explanatory diagram showing an operation of the display device according to the second embodiment of the present invention.
FIG. 21 is an explanatory diagram showing an operation of the display device according to the second embodiment of the present invention.
FIG. 22 is an explanatory diagram showing a schematic configuration of a display device according to Example 3 of the present invention.
FIG. 23 is a partial cross-sectional view of a transmissive screen of a display device according to a third embodiment of the present invention.
FIG. 24 is a partial cross-sectional view showing an example of a lenticular lens sheet of the display device according to the third embodiment of the present invention.
FIG. 25 is a partial perspective view illustrating an example of a lenticular lens sheet of the display device according to the third embodiment of the present invention.
FIG. 26 is a partial cross-sectional view of a transmissive screen according to a display device of Example 3 of the present invention.
FIG. 27 is a cross-sectional view of each member constituting the display device according to the fourth embodiment of the present invention.
FIG. 28 is an explanatory view of the axis direction of each member constituting the display device according to the fourth embodiment of the present invention.
FIG. 29 is a cross-sectional view of each member constituting the display device according to the fifth embodiment of the present invention.
FIG. 30 is an explanatory view of the axis direction of each member constituting the display device according to the fifth embodiment of the present invention.
FIG. 31 is an explanatory diagram for explaining the operation of the display device according to the fifth embodiment of the present invention;
FIG. 32 is a cross-sectional view of each member constituting the display device according to the sixth embodiment of the present invention.
FIG. 33 is an explanatory view of the axis direction of each member constituting the display device according to the sixth embodiment of the present invention.
FIG. 34 is an explanatory diagram for explaining the operation of the display device according to the sixth embodiment of the present invention.
FIG. 35 is an explanatory diagram for explaining the operation of the display device according to the sixth embodiment of the present invention.
FIG. 36 is a schematic configuration diagram for explaining the operation of the display device of the present invention.
FIG. 37 is a partial cross-sectional view of a display device according to Example 7 of the present invention.
FIGS. 38A and 38B are top views showing an overview of a mobile phone according to Embodiment 7 of the present invention. FIGS.
FIG. 39 is a block diagram showing a schematic functional configuration of a mobile phone according to Embodiment 7 of the present invention.
FIG. 40 is a top view illustrating an overview of a mobile phone according to an eighth embodiment of the present invention.
FIG. 41 is a partial cross-sectional view illustrating an example of a detachable mirror function unit according to an eighth embodiment of the invention.
FIG. 42 is a block diagram illustrating a schematic functional configuration of a drive unit of a mirror function unit according to an eighth embodiment of the invention.
FIG. 43 is a partial cross-sectional view showing an example of a display device according to Example 9 of the present invention.
FIG. 44 is a graph showing light leakage in a shutter state of a conventional display device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 100 ... Illuminating device, 200 ... Liquid crystal display panel, 208 ... Absorption type polarization selection member, 300 ... Reflection type polarization selection member, 301 ... Reflection type polarization selection member, 400 ... Transmission polarization axis variable part, 500 ... Absorption type polarization selection member , 600 ... Variable polarization selection member, 701 ... Projection device, 702 ... Mirror, 703 ... Transmission type screen.

Claims (4)

An image display unit that emits light having a first polarization state;
It is arranged to be superimposed on the image display unit, and can select either an image display state that transmits image light from the image display unit or a mirror state that reflects light traveling from the outside toward the image display unit With mirror function part,
The mirror function unit
Reflective polarization selection means arranged in order from the image display unit side;
A transmission polarization axis variable means;
An absorbing polarization means,
The reflective polarization selection means transmits a first polarized light having a predetermined polarization axis, reflects a second polarized light whose polarization axis intersects the first polarized light,
The transmission polarization axis varying means can be switched between a state in which the incident first polarized light is changed to the second polarization and transmitted and a state in which the incident light is transmitted without changing the polarization axis.
The absorptive polarization selection means transmits one of the first polarized light and the second polarized light and absorbs the other;
The image display unit is a pair of transparent substrates joined with a certain gap;
A liquid crystal layer sandwiched between these transparent substrates;
A group of pixel electrodes arranged in a matrix formed by transparent electrodes on at least one of the pair of transparent substrates;
Image light polarization selection means that transmits the first polarized light and absorbs the second polarized light disposed on the viewing side of the liquid crystal layer;
A polarizing plate disposed on the back side of the liquid crystal layer;
Furthermore, it has a lighting device arranged on its back surface,
A display device comprising switching means for switching a light emitting state of the image display unit to a non-light emitting state in conjunction with the operation when the mirror function unit is switched to a mirror state. The display device according to claim 1,
The display device characterized in that the switching means turns off the illumination device when the mirror function unit is in a mirror state. The display device according to claim 1,
The switching device is characterized in that when the mirror function unit is in a mirror state, the liquid crystal layer in the region of the image display unit that overlaps the region in the mirror state is in a dark display state. A device comprising a display device,
The display device
An image display unit for emitting image light for displaying a desired image;
A mirror function unit arranged to be superimposed on the image display unit and capable of switching between an image transmission state that transmits the image light and a mirror state that reflects external light;
The mirror function unit
Reflective polarization selection means arranged in order from the image display unit side;
A transmission polarization axis variable means;
An absorption polarization selection means,
The reflective polarization selection means transmits a first polarized light having a predetermined polarization axis, reflects a second polarized light whose polarization axis intersects the first polarized light,
The transmission polarization axis variable means can be switched between a state in which the incident first polarized light is changed to the second polarization and transmitted, and a state in which the incident light is transmitted without changing the polarization axis.
The absorptive polarization selection means transmits one of the first polarized light and the second polarized light and absorbs the other;
The reflection-type polarization selection means has a frame-like spacer having elasticity at the periphery,
The image display unit includes an image light polarization selection unit that transmits the first polarization and absorbs the second polarization, and the image display unit transmits the first polarization transmitted through the image light polarization selection unit. Equipment that emits light.

Images