JP3166367B2 - LCD display circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device,
More specifically, the present invention relates to a liquid crystal display device in which an image reading unit that reads an image signal from an optical signal is integrally formed.

[0002]

2. Description of the Related Art Conventionally, a liquid crystal display device has only a function of displaying an image signal. To add an image reading function of reading an image signal from an optical signal to the liquid crystal display device,
It was necessary to provide an image reading device separately from the liquid crystal display device.

[0003] Therefore, it is desired that the image reading device and the liquid crystal display device are integrally formed.

[0004]

However, when the image reading device and the liquid crystal display device are simply integrated, a switching element for each pixel for the image reading device and a switching element for each pixel for the liquid crystal display device are required. Since two switching elements must be formed for each pixel, the wiring becomes complicated and the formation of the switching elements becomes extremely fine. Therefore, there is a problem that it is difficult to manufacture a liquid crystal display device integrated with the image reading device, and the yield is deteriorated.

Accordingly, the present invention has been made in view of the above circumstances, and shares a switching element for each pixel for image reading and a switching element for each pixel for liquid crystal display, and a common use of a photoelectric conversion element. By connecting the terminal opposite to the terminal connected to the switching element to the next-stage gate line, the manufacturing is simplified, and the switching element is easily formed and the manufacturing yield is improved. It is an object of the present invention to provide a liquid crystal display device which can be operated.

[0006]

SUMMARY OF THE INVENTION The present invention provides a signal line and signal line.
A liquid crystal display device configured such that a switching element and a liquid crystal capacitor are connected in series between a scanning line and a common electrode of the liquid crystal through a source terminal of the switching element. the source terminal, the photoelectric conversion element is connected in parallel to the liquid crystal capacitance, as well as integrally formed by connecting the other end of the terminal and the switching element side of the photoelectric conversion element to the next scan line, the photoelectric For conversion element
Output the read data through the switching element.
With the provision of the means described above, the above object is achieved.

[0007]

According to the present invention, a liquid crystal capacitor connected in parallel with a switching element in series and a photoelectric conversion element are connected, and a terminal of the photoelectric conversion element opposite to the switching element is connected to a next scanning line. The switching element for each pixel for image reading and the switching element for each pixel for liquid crystal display can be shared, and only one switching element is formed for each pixel. Not only that, the terminal on the side opposite to the switching element can be connected to a different line between the photoelectric conversion element and the liquid crystal capacitor, so that the wiring can have a margin. As a result, the switching elements can be formed easily and easily, and the yield in manufacturing can be improved.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to embodiments.

FIGS. 1 and 2 show an embodiment of the liquid crystal display device of the present invention.

FIG. 1 is a circuit diagram of a liquid crystal display device 1 according to the present invention, in which a plurality of signal lines 2 and a plurality of gate lines (scan lines) 3 are arranged in a matrix.
In addition, the same number of common electrodes 4 as the gate lines 3 are arranged in parallel with the gate lines 3. A dummy gate line 3A is provided at the last stage of the gate line 3 (the lowest stage in FIG. 1).

An N-channel MOS TFT (film transistor) 5 is provided between each of the signal lines 2 and the common electrode 4.
And the liquid crystal capacitor 6 are connected in series.
And a photoelectric conversion element 7 and an auxiliary capacitor 8 are connected in parallel.

The photoelectric conversion element 7 is formed of an a-Si photodiode or the like, and becomes conductive when light reflected from a document or the like or light irradiated by a light pen or the like is applied. It becomes an insulated state.

Each of the N-channel MOS TFTs (switching elements) 5 has a gate connected to the gate line 3, a drain connected to the signal line 2, and a source connected to the liquid crystal 6, the photoelectric conversion element and the auxiliary capacitor 8. It is connected. The gate line 3 is connected to a scanning drive circuit 9 including a shift register and the like.
The liquid crystal capacitor 6 and the auxiliary capacitor 8 each have a terminal opposite to the N-channel MOS TFT 5 at the common electrode 4.
It is connected to the. The photoelectric conversion element 7 has a terminal on the opposite side to the N-channel MOS TFT 5 connected to the next gate line 3.
TFT 5, liquid crystal capacitor 6, photoelectric conversion element 7, and auxiliary capacitor 8
Constitutes one pixel as a whole, and the pixel is formed every time the plurality of gate lines 3 and the common electrode 4 intersect. In the lowermost pixel in FIG. 1, the terminal of the photoelectric conversion element 7 on the side opposite to the N-channel MOS TFT 5 is connected to the dummy gate line 3A.

Each of the signal lines 2 has a first transfer gate (CMOS-TFT for signal switching) 1
0 and a second transfer gate (CMOS-TFT for signal switching) 1
The first transfer gate 10 and the second transfer gate 11 are provided for each signal line 2. And
The second non-control terminal of the first transfer gate 10 is
The second non-control terminal of the second transfer gate is connected to the display data input terminal 12 and the read data output terminal 1
3 is connected. Further, the P-side control terminal of the first transfer gate 10 and the N-side control terminal of the second transfer gate 11 are commonly connected, and are also connected to a signal side driving circuit 14 composed of a shift register or the like. Further, the N-side control terminal of the first transfer gate 10 and the P-side control terminal of the second transfer gate are commonly connected and connected to the signal side drive circuit 14.

FIG. 2 is a side cross-sectional view of the N-channel MOS TFT 5 and the photoelectric conversion element 7 of the liquid crystal display device 1, and is formed by depositing thin films by vapor deposition sputtering, plasma CVD, etching, or the like.

That is, in FIG. 2, a red, blue, and green color filter 22, a transparent insulating film 23, and an opaque insulating film 24 are formed on a first glass substrate 21 in a predetermined pattern. 22, transparent insulating film 2
The common electrode 3 is formed on the insulating film 3 and the opaque insulating film 24 with the insulating film 25 interposed therebetween. An alignment film 26 is formed on the common electrode 3 by lamination.

On the other hand, an opaque anode electrode 28 and an insulating film 29 are formed in a predetermined pattern on the second glass substrate 27. On the anode electrode 28, n ⁺ a-Si Layer 30, ia-Si layer 31, and p ⁺
The a-Si layer 32 is formed by sequentially laminating. This p
^A transparent cathode electrode 33 is sequentially formed on the ⁺ a-Si layer 32, and the outside of the cathode electrode and the n ⁺ a-Si layer 30, the ia-Si layer 31, and the p ⁺ a-
On the outside of the Si layer 32, an opaque insulating film 34 is formed by lamination.

On the insulating film 29, the insulating film 35 and the silicon film 36 are laminated in a predetermined pattern. On the silicon film 36, an opaque insulating film 37,
Gate electrode 38, drain electrode 39 and source electrode 40
Are laminated in a predetermined pattern. And
On the surface of the second glass substrate 27, an alignment film 41 is formed by lamination.

The first glass substrate 2 thus configured
The first alignment film 26 and the alignment film 41 of the second glass substrate 27 are opposed to each other at a predetermined interval, and a liquid crystal 42 is filled between the alignment film 26 and the alignment film 41.

The anode electrode 28, n ⁺ a-
Si layer 30, ia-Si layer 31, p ⁺ a-Si layer 32
And the cathode electrode 33 constitute an a-Si photodiode as the photoelectric conversion element 7. The silicon thin film 36, the opaque insulating film 37, the gate electrode 38, the drain electrode 39, and the source electrode 40 are formed of the N-channel MOST.
A TFT as FT5 is configured.

Next, the operation will be described.

<Image Reading Operation> First, the case of reading an image will be described.

In the liquid crystal display device 1, when a gate signal is supplied from the scanning drive circuit 9 to the gate line 3, the N-channel MOS TFT 5 is turned on, and the photoelectric conversion element 7 and the signal line 2 conduct. In this state, the signal side drive circuit 14
The low level is sequentially supplied to the N-side control terminal of the first transfer gate 10 and the P-side control terminal of the second transfer gate 11, and the P-side control terminal of the first transfer gate 10 and the second transfer gate Gate 11
When a high level is supplied to the N-side control terminal, the first transfer gate 10 is turned off, only the second transfer gate 11 is sequentially turned on, and the read data for each pixel generated by the photoelectric conversion element 7 is output. Are sequentially output to the read data output terminal 13.

In this case, the liquid crystal capacitance 6 and the auxiliary capacitance 8 are
Since it has a high impedance, it does not affect reading.

<Image Display Operation> Next, the case of displaying an image will be described.

In the liquid crystal display device 1, when a gate signal is supplied from the scanning drive circuit 9 to the gate line 3, the N-channel MOS TFT 5 is turned on, and the signal line 2 is electrically connected to the liquid crystal capacitor 6 and the auxiliary capacitor 8. . In this state, when light is not irradiated, the photoelectric conversion element 7 has a high impedance and does not affect display.

In this state, a low level is sequentially supplied to the P-side control terminal of the first transfer gate 10 and the N-side control terminal of the second transfer gate 11 from the signal side drive circuit 14, and the first transfer gate When a high level is supplied to the N-side control terminal of the gate 10 and the P-side control terminal of the second transfer gate 11, the second transfer gate 11 is turned off and only the first transfer gate 10 is sequentially turned on. The image display data input from the display data input terminal 12 is sequentially supplied to the liquid crystal capacitor 6 and the auxiliary capacitor 8 through the signal line 2 so that the image can be displayed in the same manner as a normal active matrix LCD.

When the photoelectric conversion element 7 connected to a certain gate line 3 is in a selected state, the next-stage gate line 3 is always in a non-selected state, for example, at a ground level voltage. Therefore, even if the terminal of the photoelectric conversion element 7 on the side opposite to the N-channel MOS TFT 5 is connected to the gate line 3 of the next stage, the above operation is performed normally.

The spectral sensitivity characteristic of the photoelectric conversion element 7 is as follows.
Insensitive to visible light, for example, using a material that is sensitive to infrared light, a light pen is also required to be able to irradiate light with high sensitivity, but appropriately select the material of the photoelectric conversion element,
Alternatively, it is possible by appropriately selecting the conditions for forming the film.

[0030]

According to the present invention, a photoelectric conversion element is connected in parallel to a liquid crystal capacitor connected in series with a switching element.
It is, configured Then together integrally by connecting the other end of the terminal and the switching element side of the photoelectric conversion element to the next scan line
The data read by the photoelectric conversion element is
Since the includes a means for outputting via a grayed element, it is possible to share the switching element for each pixel switching element and the liquid crystal display of each pixel for output pixel readout, one switching element for each pixel Not only is it sufficient to form them, but also the terminal opposite to the switching element can be connected to different lines for the photoelectric conversion element and the liquid crystal capacitor, so that the wiring can have a margin. As a result, the switching elements can be formed easily and easily, and the yield in manufacturing can be improved.

[Brief description of the drawings]

FIG. 1 is a circuit diagram of a liquid crystal display device according to the present invention.

FIG. 2 is an N-channel MOS TF of the liquid crystal display device of FIG.
FIG. 4 is a side sectional view of T and a part of the photoelectric conversion element.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Liquid crystal display device 2 Signal line 3 Gate line 4 Common electrode 5 N-channel MOS TFT 6 Liquid crystal capacity 7 Photoelectric conversion element 8 Auxiliary capacity 9 Scan side drive circuit 10 First transfer gate 11 Second transfer gate 12 Display data input terminal Reference Signs List 13 read data output terminal 14 signal side drive circuit 21 first glass substrate 22 color filter 23 transparent insulating film 24 opaque insulating film 25 insulating film 26 alignment film 27 second glass substrate 28 anode electrode 29 insulating film 30 n ⁺ a- Si layer 31 ia-Si layer 32 p ⁺ a-Si layer 33 cathode electrode 34 insulating film 35 insulating film 36 silicon thin film 37 opaque insulating film 38 gate electrode 39 drain electrode 40 source electrode 41 alignment film 42 liquid crystal

Claims (1)

(57) [Claims] 1. A switching element and a liquid crystal capacitance between the signal line and the scanning line and the liquid crystal of the common electrode is the switching
In a liquid crystal display device configured to be connected in series via a source terminal of an element, a photoelectric conversion element is provided at a source terminal of the switching element.
A terminal is connected in parallel with the liquid crystal capacitor, and a terminal on the side opposite to the switching element side of the photoelectric conversion element is connected to the next scanning line to be integrally formed , and the photoelectric conversion element is used.
A means for outputting read data via the switching element
A liquid crystal display device comprising the stage.