JP2000298253A - Liquid crystal display device with image pickup function, computer, television telephone, and digital camera - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the liquid crystal display device, etc., with the image pickup function which will not be in a line of sight in unnatural direction and makes a user unaware of the attachment of an image pickup device. SOLUTION: This device has a liquid crystal display panel 12, which can have transitions between a colored state and a transparent light-transmission state, cell by cell, a liquid crystal driving means 21 which controls the coloration and light transmission of each cell, a light scattering means 14, which is provided between the liquid crystal panel and an image pickup optical system opposite the image pickup optical system and has transition between a light scatter state and a transparent state, and a light scatter control means 23 which controls the light scatter state of the light scattering means 14. The light scatter control means 23 allows the light scattering means 14 to have transition between the light scatter state and transparent state, when the light scattering means 14 is in the transparent state, the liquid crystal driving means 21 places the liquid crystal panel in the light transmission state and an image pickup driving 22 makes a solid image pickup element 13 active, whereas when the light scattering means 14 is in the light scatter state, the liquid crystal drive means 21 places the liquid crystal in the colored state and the image pickup drive means 22 makes the solid image pickup element inactive.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a case where a user displays his / her own face on a liquid crystal display panel display, or his / her own face on a communication partner terminal display in bidirectional communication including image transfer such as a so-called videophone. , A liquid crystal display device with an imaging function that does not make the eyes look unnatural and does not make the user aware that the imaging device is attached, a computer having the display device as a display, the television phone And the digital camera.

[0002]

2. Description of the Related Art Conventionally, there has been known a liquid crystal display device having an image pickup device mounted on an upper portion of a color liquid crystal display panel. This display device
For example, it is applied to a laptop computer, a so-called video conference system or a video phone. In a laptop computer, the user's own face can be displayed on the display as a portrait, and if necessary, the portrait displayed on the display can be printed out. In this case, since the user's line of sight usually points to the top of the display, the line of sight of the captured portrait will point to the bottom.

[0003] Of course, it is possible to capture the face image displayed at that time by looking at the imaging apparatus, but since the user cannot see his / her own face at the moment of capturing the image, the user is not necessarily able to capture the face. Can't get the portrait he likes. Further, also in the case of a television conference system, the speaker's gaze displayed on the display of the conference terminal device tends to be downward. In order to avoid this, each conference participant must always be conscious and try to look at the imaging device on the upper part of the display, and a natural conversation environment between the conference participants cannot be created. This also applies to the videophone, and there is a disadvantage that the line of sight of the conversation partner displayed on the display always faces downward.

On the other hand, there is also known a liquid crystal display device in which a central part of a liquid crystal display panel is removed and an image pickup device is fitted in the removed portion (for example, see Japanese Patent Application Laid-Open No. 1-142786). In this liquid crystal display device, no image is displayed at the center of the display, and usually appears as a black circular area. For this reason, this imaging device is unsuitable for application to the laptop computer, the video conference system, the video phone, and the like.

An object of the present invention is to display a user's own face on a liquid crystal display panel display, or to display a user's own face on a communication partner terminal display in bidirectional communication including image transfer such as a so-called videophone. In the case of displaying, the liquid crystal display device does not make the user's eyes aware that the line of sight does not become an unnatural direction and furthermore, the display device has the display device,
It is to provide a computer, a videophone and a digital camera.

[0006]

Means for Solving the Problems In order to achieve the above object, the present inventors have used a liquid crystal display panel which can transition between a colored state and a transparent state, and have a specific type of liquid crystal display device. The present invention has been made based on the finding that if the device is devised, the imaging device can be arranged on the back surface without removing a part of the center of the liquid crystal display panel.

A liquid crystal display device with an image pickup function according to the present invention has a liquid crystal display panel, a liquid crystal drive unit, an image pickup optical system, an image pickup drive unit, a light scattering unit, and a backlight source.
The liquid crystal display panel has a structure capable of transitioning between a light non-transmissive state and a transparent light transmissive state on a cell basis. For example, a panel having a three liquid crystal layer structure driven by liquid crystal driving means of a subtractive color mixing method described later is used. used. The imaging optical system of the imaging device includes a solid-state imaging device (charge-coupled device) driven by imaging driving means, and is arranged on the back of the liquid crystal display panel. The imaging optical system includes at least one lens, and can include a focus adjustment mechanism, a prism, and the like. The light scattering means (a polymer-dispersed liquid crystal can be used) is provided between the liquid crystal display panel and the imaging optical system at a portion where the imaging optical system is located. And it is controlled by the light scattering control means. For example, a backlight source composed of a cathode ray tube or the like is provided at a position behind the light scattering means, which does not conflict with the solid-state imaging device.

In the present invention, the light scattering control means causes the light scattering means to alternately transition between a light scattering state and a transparent state, and during a period in which the light scattering means is in a transparent state, The liquid crystal driving unit causes the liquid crystal panel to transition to a light transmitting state, the imaging driving unit activates the solid-state imaging device, and the liquid crystal driving unit operates while the light scattering unit is in the light scattering state. Causes the liquid crystal panel to transition to a color-developing state, and the imaging drive unit captures an image of a subject in front of the liquid crystal display panel by inactivating the solid-state imaging device. That is, while the solid-state imaging device is active and the light scattering means is in the transparent state, no light from the backlight source is supplied to the liquid crystal display panel, so that the liquid crystal display panel does not function as a display device. In addition, since the liquid crystal display panel is in a transparent state, light from the subject can be taken into the imaging device. While the solid-state imaging device is inactive and the light scattering means is in a light scattering state, the liquid crystal display panel is supplied with light from a backlight source and functions as a display device. Color development.

In order to perform such an operation, the control of the solid-state imaging device by the imaging driving means, the control of the light scattering means by the light scattering control means, and the control of the liquid crystal display panel by the liquid crystal driving means are synchronized. Needs to be taken. When this synchronization is obtained in N cycles (N is, for example, about 40 to 100), the imaging driving unit activates the solid-state imaging device at N frames / sec, and the light scattering control unit sets the transparent state and the light scattering state in N cycles. The state is alternately changed, and the liquid crystal driving means drives each cell of the liquid crystal display panel at N frames / sec.

In the liquid crystal display device of the present invention, a monochrome liquid crystal display panel may be used, but usually a color liquid crystal display panel is used. The color liquid crystal display panel includes three liquid crystal layers doped with a cyan dye, a magenta dye, and a yellow dye, and a liquid crystal driving unit can control each liquid crystal layer by subtractive color mixing of the three liquid crystal layers. In the subtractive color mixture of the three liquid crystal layers, the cell becomes black when all three layers are off for the corresponding region, and turns red when only the cyan dye-doped liquid crystal layer is on, and becomes magenta-doped liquid crystal. When only the layer is turned on, it turns green,
When only the liquid crystal layer doped with the yellow dye is turned on, the color becomes blue, and when all three layers are turned on, the color becomes white.

Further, the liquid crystal display device of the present invention comprises: a liquid crystal display panel capable of transitioning between a colored state and a transparent light transmitting state on a cell-by-cell basis; and a liquid crystal driving means for controlling color development and light transmission for each of the cells. An optical system including a solid-state imaging device disposed on the back of the liquid crystal display panel, imaging driving means for driving the solid-state imaging device, and a position behind the solid-state imaging device behind the light scattering means which does not conflict with the solid-state imaging device A backlight source provided at the site, which can be turned on and off intermittently, and a backlight driving means for driving the backlight on and off intermittently, wherein the backlight source is turned off The liquid crystal driving means causes the liquid crystal panel to transition to the light transmitting state, the imaging driving means activates the solid-state imaging device, and the backlight source is turned off. During the period, the liquid crystal driving unit causes the liquid crystal panel to transition to a color developing state, and the imaging driving unit inactivates the solid-state imaging device, thereby capturing an image of a subject in front of the liquid crystal display panel. Is the gist.

In this case, a semiconductor light emitting device can be used as a backlight source.

The above-described liquid crystal display device is suitably applied to a display of a computer, a display of a videophone, or a digital camera.

In a laptop computer,
When the user's own face is displayed on the display as a portrait, the user's line of sight naturally points on the display, that is, the liquid crystal display device, so that the line of sight of the captured portrait is directed to a direction other than the front. Such inconvenience does not occur. Therefore, the portrait that the user liked can be obtained. Also, in the case of the television conference system, since the speaker's eyes displayed on the display of the conference terminal device do not face downward, a natural conversation environment between the conference participants can be created. Further, in the case of a videophone, the eyes of the conversation partner displayed on the display always face the front, so that no discomfort occurs.

Further, according to the present invention, the above-mentioned Japanese Patent Laid-Open No.
A liquid crystal display device can be provided without removing a part of the center as in the liquid crystal display panel described in 142,786. Therefore, since a black circular area does not occur at the center of the display, application to a laptop computer, a video conference system, a video phone, and the like is suitably performed.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of a liquid crystal display device with an image pickup function according to the present invention will be described below with reference to FIGS.

FIG. 1 shows a liquid crystal display device 100 having an imaging function.
FIG. In FIG. 1, a liquid crystal display panel 12 is mounted on the surface of a display unit casing 11, and a solid-state imaging device (CCD camera) 13 is disposed on the back side thereof. Light scattering means 14 composed of a polymer dispersed liquid crystal plate is provided between the solid-state imaging device 13 and the liquid crystal display panel. On the same surface as the light scattering means 14, a light scattering plate 1 doped with light scattering particles so as to surround the light scattering means 14.
5 is attached. A backlight source 16 such as a cold-cathode tube is provided in a part behind the light scattering means 14 and not in position with the solid-state imaging device 13. In addition, the solid-state imaging device 13 includes a focus adjustment mechanism 17 that moves a lens (not shown) in the optical axis direction.

Each cell of the liquid crystal display panel 12 is driven by a liquid crystal driving unit 21, and the solid-state imaging device 13 is driven by an imaging driving unit 22. Further, the light scattering means 14 controls the light scattering control means 2 so as to be in a light scattering state or a transparent state.
3 is controlled. The light scattering plate 15 always exhibits constant light scattering, and light scattering is not controlled. The focus adjustment mechanism 17 is controlled by a focus control unit 24. The focus control means 24 may be a dial operated by a user, a control means having an autofocus function, or a soft dial operated by a mouse pointer or the like. .

The solid-state imaging device 13 image data GD captured by is sent to the image processing unit 25, is converted into the display data DD _0, when stored in the memory 26, or immediately want to display is sent to the frame buffer 27 . The display data D is stored in the frame buffer 27.
D In addition to _0, for example, to display data DD ₁ stored in the memory 26 may also be transferred, sometimes the display data DD ₂ from a network (not shown) is transferred.

The synchronizing clock SYNC_CLK (here, 60 cycles) from the synchronizing means 28 is input to the liquid crystal driving means 21, the imaging driving means 22, and the light scattering control means 23. This synchronization clock SYNC_
CLK is a frame rate of an image displayed on the liquid crystal display panel 12 at the time of imaging, a frame rate of image capturing in the solid-state imaging device 13, and a light scattering unit 14.
Governs the transition between the light scattering state and the transparent state.
In the present embodiment, the image displayed on the liquid crystal display panel 12 is displayed every 1/60 [second], and the image pickup by the solid-state imaging device 13 is also performed every 1/60 [second]. The transition between the light scattering state and the transparent state of the means 14 is performed every 1/60 [second], but the image display, the image capture, and the transition of the light scattering state at such a rate are currently performed. It can be realized very easily with the technical level of.

FIG. 2 shows a synchronization clock SYNC_CLK.
And the driving output signal L_C of the liquid crystal driving unit 21, the driving output signal C_C of the imaging driving unit 22, and the light scattering control unit 2.
3 shows the relationship with the control output signal S_C. As shown in FIG. 2, the liquid crystal driving means 21 operates at 60 frames / sec.
Drives the respective cells of the liquid crystal display panel 12, the imaging driving means 22 activates a charge-coupled device 132 of the solid-state imaging device 13 described later at 60 frames / sec, and the light scattering control means 23 controls the light scattering means 14 in 60 cycles. Alternately transition between the transparent state and the light scattering state.

FIGS. 3A and 3B are diagrams for explaining the operation of the present embodiment, in which the liquid crystal display panel 12, the solid-state imaging device 13,
The light scattering means 14 is shown in an enlarged manner. Note that these are schematic views, and the size of each member is exaggerated. Therefore, the illustrated size is different from the actual size of the writing member.

3A and 3B, the liquid crystal display panel 12 has three liquid crystal layers LCD ₁ , LCD ₂ , and LCD _3.
And each liquid crystal layer has four glass plates G ₀ , G ₁ , G
It is arranged so as to be sandwiched between the _2, G _3. 0 th liquid crystal layer LCD ₁ side of the glass plate G ₀ (most surface side), respectively the first liquid crystal layer LCD ₂ side of the glass plate G _1, the second liquid crystal layer LCD ₃ side of the glass plate G ₂ of the first 1 Transparent electrode T
P _11, TP _12, TP ₁₃ is formed, the first liquid crystal layer LCD ₁ side of the glass plate G _1, 2-th liquid crystal layer LCD ₂ side of the glass plate G _2, the third glass sheet G ₃ Liquid crystal layer LCD ₃
Each of the side second transparent electrode TP _21, TP _22, TP ₂₃ are formed. The liquid crystal layer LCD ₁ is made of a liquid crystal doped with a cyan dye, the LCD ₂ is made of a liquid crystal doped with a magenta dye, and the LCD ₃ is made of a liquid crystal doped with a yellow dye.

3A and 3B, the solid-state imaging device 13 includes a lens 131 and a charge-coupled device (CCD) 132 as an imaging optical system. Although an example using only one lens (lens 131) is shown here, a plurality of lenses can be used.

FIG. 3A shows a state in which the charge-coupled device 132 is inactive and each cell of the liquid crystal display panel 12 is in a colored state. As also shown in Figure 2 (see FIG TR _1), the light scattering means 14 is in a light scattering state in this case, the backlight source 16 (see FIG. 1 is irradiated directly on the light scattering means 14 together with a part of the light L ₀ is emitted scattered liquid crystal display panel 12 side from), the scattered light L ₁ transmitted from the light scattering plate 15 to the liquid crystal display panel 12 side in the light scattering means 14 parts Irradiated
The display light _Ldisp is emitted from the surface of the liquid crystal panel 12. As a result, all the cells of the LCD ₁ , LCD ₂ , and LCD _{3 in the} voltage-off state exhibit black, only the liquid crystal layer LCD ₁ doped with the cyan dye exhibits a red cell in the cell having the voltage on, and the magenta dye does not. Liquid crystal layer LCD
Only ₂ exhibited a cell a green voltage on, only the liquid crystal layer LCD ₃ yellow dye doped is exhibited cell blue voltage on and LCD _1, LCD _2, all LCD ₃ is the cell voltage on It is white.

FIG. 3B shows a state in which the charge-coupled device 132 is activated and the liquid crystal display panel 12 is driven to be in a transparent state. As shown in FIG. 2 (see TR2 in FIG. ₂ ), at this time, since the light scattering means 14 is in a transparent state, the backlight source 16 directly irradiating the light scattering means 14 (see FIG. 1). Light L from
A part of ₀ may be totally reflected by the light scattering means 14 and be irradiated on the charge-coupled device 132 side. However, since this light has a large incident angle, it does not enter the charge-coupled device 13. Therefore, the captured image hardly contains noise. A part of the light L ₀ from the backlight source 16 may pass through the light scattering means 14 and irradiate the liquid crystal display panel 12 side. However, since this light also has a large incident angle, the liquid crystal display It does not contribute to the display of each cell of panel 12. Therefore, flickering or the like does not occur in the image displayed on the liquid crystal display panel 12.

On the other hand, the light L _cap from the subject is applied to the charge-coupled device 132 through the lens 131 because the liquid crystal display panel 12 and the light scattering means 14 are in a transparent state.

FIG. 4 illustrates a second embodiment of the liquid crystal display device with an image pickup function according to the present invention, with reference to FIGS.

FIG. 4 shows a liquid crystal display device 101 having an imaging function.
FIG. In FIG. 4, components denoted by the same reference numerals as those in FIG. 1 are the same as the components in FIG. In FIG. 1, a liquid crystal display panel 12 is mounted on the surface of a display casing 11, and a solid-state imaging device 13 is disposed on the back side thereof. A backlight source 31 is provided on a portion of the back surface of the liquid crystal display panel 12 which does not conflict with the solid-state imaging device 13. In addition, the solid-state imaging device 13 includes a focus adjustment mechanism 17 that moves a lens (not shown) in the optical axis direction.

In the second embodiment, as in the first embodiment, each cell of the liquid crystal display panel 12 is driven by the liquid crystal driving means 21, and the solid-state imaging device 13 is driven by the imaging driving means 22. The backlight source 31 includes a semiconductor light emitting element (eg, a plurality of white LEDs) and is controlled by a backlight driving unit 32. Focus adjustment mechanism 17
Is controlled by the focus control unit 24, and the solid-state imaging device 1
The image data GD captured by the image processing unit 3
5 is converted to display data DD ₀ and stored in the memory 2
6 or sent to the frame buffer 27 when it is desired to display it immediately.

The synchronizing clock SYNC_CLK (here, 60 cycles) from the synchronizing means 28 is input to the liquid crystal driving means 21, the imaging driving means 22, and the backlight source 31. This synchronization clock SYNC_
CLK controls the frame rate of an image displayed on the liquid crystal display panel 12 at the time of imaging, the frame rate of image capture in the solid-state imaging device 13, and the on / off of the backlight source 31. In this embodiment, the image displayed on the liquid crystal display panel 12 is 1/60
While the display is performed every [second], the image capturing in the solid-state imaging device 13 is also performed every 1/60 [second], and the on / off of the backlight source 31 is performed every 1/60 [second]. The image display, the image capture, and the on / off at such a rate can be realized very easily with the current technical level.

FIG. 5 shows a synchronization clock SYNC_CLK.
And a drive output signal L_C of the liquid crystal drive unit 21, a drive output signal C_C of the imaging drive unit 22, and a control output signal B_C of the backlight drive unit 32. The liquid crystal driving means 21 operates the liquid crystal display panel 1 at 60 frames / sec.
2 is driven, and the imaging driving unit 22 operates at 60 frames / sec.
32 is active, and the backlight driving means 32
On / off of the backlight source 31 is alternately performed in 0 cycle.

FIGS. 6A and 6B are explanatory diagrams of the operation of the present embodiment, in which the liquid crystal display panel 12, the solid-state imaging device 13,
In addition, the backlight source 31 is shown in an enlarged manner. 6A and 6B, FIGS. 3A and 3B
3 are the same as those in FIG.
The components are the same as those of (A) and (B).

FIG. 6A shows a state in which the charge-coupled device 132 is inactive and each cell of the liquid crystal display panel 12 is in a colored state. As also shown in Figure 5 (see FIG TR _1), since the backlight source 31 is turned on at this time, the light L ₀ from the backlight source 31
_Are emitted from the liquid crystal display panel 12 as display light _Ldisp , and each cell emits a desired color.

FIG. 6B shows a state in which the charge-coupled device 132 is activated and the liquid crystal display panel 12 is driven to be in a transparent state. Figure (see FIG TR ₂₎ as also shown in 5, the backlight source 3 in this case
1 is off. Thereby, the solid-state imaging device 13
_Receives light L _cap from the subject.

[0036]

According to the present invention, the liquid crystal display device can be provided without removing a part of the center, so that a black circular area does not occur at the center of the display.
Accordingly, application to a laptop computer or two-way communication including image transfer (television conference system, videophone, etc.) is suitably performed.

That is, in the computer of the present invention, when the user's own face is displayed as a portrait on the display, the user's line of sight naturally points to the center of the liquid crystal display device. However, there is no inconvenience that the user faces in a direction other than the front. Therefore, the user can obtain his / her own favorite portrait. In addition, even when the above-mentioned computer is used as a conference terminal device of a television conference system, since the eyes of the speaker displayed on the display do not face downward, it is necessary to create a natural conversation environment between the conference participants. Can be.

Also, in the videophone of the present invention, as described above, the eyes of the conversation partner displayed on the display always face the front, so that no discomfort occurs.

[Brief description of the drawings]

FIG. 1 is an overall view showing a first embodiment of a liquid crystal display device with an imaging function according to the present invention.

FIG. 2 is a block diagram showing a configuration of the liquid crystal display device shown in FIG. 1 with a synchronization clock SYNC_CLK and a drive output signal L_
FIG. 3C is a diagram illustrating a relationship between C, a drive output signal C_C of the imaging drive unit, and a control output signal S_C of the light scattering control unit.

FIG. 3 is an operation explanatory diagram of the liquid crystal display device of FIG. 1;
(A) is a diagram showing a state in which the charge-coupled device is inactive and each cell of the liquid crystal display panel is in a colored state;
(B) is a diagram showing a state in which the charge-coupled device is active and the liquid crystal display panel is driven to be in a transparent state.

FIG. 4 is an overall view showing a second embodiment of the liquid crystal display device with an imaging function according to the present invention.

FIG. 5 is a block diagram showing a configuration of the liquid crystal display device shown in FIG. 4, in which a synchronization clock SYNC_CLK and a drive output signal L_
FIG. 3C is a diagram illustrating a relationship between C, a drive output signal C_C of the image pickup drive unit, and a drive output signal B_C of the backlight drive unit.

6 is an operation explanatory view of the liquid crystal display device of FIG. 4,
(A) is a diagram showing a state in which the charge-coupled device is inactive and each cell of the liquid crystal display panel is in a colored state;
(B) is a diagram showing a state in which the charge-coupled device is active and the liquid crystal display panel is driven to be in a transparent state.

[Explanation of symbols]

Reference Signs List 11 display casing 12 liquid crystal display panel 13 solid-state imaging device 14 light scattering means 15 light scattering plate 16 backlight source 17 focus adjustment mechanism 21 liquid crystal driving means 22 imaging driving means 23 light scattering control means 24 focus control means 25 image processing means 26 memory 28 synchronization means 31 backlight source 32 backlight drive means 100 and 101 drive the output signals of the liquid crystal display device 131 lens 132 charge-coupled device DD _0, DD _1, DD ₂ display data SYNC_CLK synchronous clock L_C liquid crystal driving section 21 C_C control output signal LCD ₁ of the driving output signal S_C light scattering control unit 23 of the imaging drive unit 22, LCD _2, LCD ₃ crystal layer _{G 0, G 1, G 2} , G 3 glass plate TP _11, TP _12, TP ₁₃ second first transparent electrode TP _21, TP _22, TP ₂₃ second transparent electrode L ₀ back Light from the direct light L _disp display light L _cap object from site source

Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat II (reference) G09F 9/00 332 G09F 9/00 332C 5C058 364 364N 5C064 9/35 390 9/35 390 5C080 G09G 3/20 691 G09G 3 / 20 691G 5C094 3/36 3/36 5G435 H04N 5/225 H04N 5/225 FD 5/66 102 5/66 102A 102B 7/14 7/14 7/14 F term (reference) 2H054 AA01 2H088 EA14 EA15 EA25 GA13 HA28 JA06 MA16 2H089 HA02 KA20 QA16 RA06 TA07 UA09 5C006 AA22 AB05 EC02 5C022 AA12 AA13 AC03 AC42 AC51 AC69 5C058 AA06 AB02 AB03 BA01 BA35 BB13 5C064 AA01 AA02 AA04 AB02 AB04 AC03 AC04 AC12 5C080 AA01 EJB05 EB07 EB03 EB07 BA43 CA24 DA03 DA12 ED13 HA08 5G435 AA00 BB12 BB15 CC12 DD01 EE25 EE30 FF06 GG02 LL04 LL08 LL14

Claims (6)

[Claims] 1. A liquid crystal display panel capable of transitioning between a colored state and a transparent light transmitting state on a cell-by-cell basis; liquid crystal driving means for controlling color development and light transmission for each of the cells; An imaging optical system including the solid-state imaging device, an imaging driving unit for driving the solid-state imaging device, and a portion provided between the liquid crystal display panel and the imaging optical system, where the imaging optical system is located. A light scattering means capable of transiting between a light scattering state and a transparent state; a light scattering control means for controlling a light scattering state of the light scattering means; And a backlight source provided at a portion not to be provided, wherein the light scattering control means alternately transitions the light scattering means between a light scattering state and a transparent state, and the light scattering means Transparent During the period, the liquid crystal driving means causes the liquid crystal panel to transition to the light transmitting state, the imaging driving means activates the solid-state imaging device, and the light scattering means is in the light scattering state. During the period, the liquid crystal driving unit causes the liquid crystal panel to transition to a color developing state, and the imaging driving unit inactivates the solid-state imaging device to image a subject in front of the liquid crystal display panel.
A liquid crystal display device with an imaging function, characterized in that: 2. The liquid crystal display panel comprises three liquid crystal layers doped with a cyan dye, a magenta dye, and a yellow dye, and the liquid crystal driving means controls each of the three liquid crystal layers by subtractive color mixing. The liquid crystal display device with an imaging function according to claim 1. 3. The liquid crystal display device with an imaging function according to claim 1, wherein the light scattering means is a polymer dispersed liquid crystal. 4. A computer having a liquid crystal display device with an imaging function according to claim 1 as a display. 5. A videophone having the liquid crystal display device with an imaging function according to claim 1 as a display. 6. A digital camera having the liquid crystal display device with an imaging function according to claim 1 as a display.