JP3064737B2 - Image input / output device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image input / output device, and more particularly to an image input / output device having an image reading unit using a two-dimensional sensor.

[0002]

2. Description of the Related Art Conventionally, a thin and lightweight liquid crystal display is often used as a portable image display device for displaying image information. In recent years, a portable image input / output device having not only an image display function but also an image reading function has been desired. By the way, there are so-called one-dimensional sensors and two-dimensional sensors for reading an image, and these may be used as an image input unit of an image input device.

[0003]

However, the image input unit using the one-dimensional sensor manually or mechanically moves the one-dimensional sensor or the original to be read in a direction orthogonal to the longitudinal axis of the one-dimensional sensor. A mechanism is needed to make this happen. In particular, in a structure in which the one-dimensional sensor is mechanically moved, a mechanism for moving the one-dimensional sensor is required. Not suitable. If the one-dimensional sensor is manually moved with respect to the document and this is used as the image input unit of the image input / output device, the size of the image input unit can be reduced, but the moving speed and moving direction can be maintained accurately. There was a problem that the user had to operate while operating.

Further, as a so-called two-dimensional sensor used as an image input unit, for example, a structure in which a liquid crystal display substrate and a substrate on which a two-dimensional sensor is arranged may be simply used. There is a problem that the weight of the entire apparatus becomes large, and a small, lightweight, and portable image input / output apparatus cannot be obtained.

The present invention has been made in view of the above circumstances, and provides an image input / output device having a small, lightweight, and simple structure.

[0006]

[MEANS FOR SOLVING THE PROBLEMS] To achieve the above object
The invention according to claim 1 includes a plurality of display elements and a plurality of photoelectric conversion elements.
Image input / output device in which
Connected to the photoelectric conversion element in series and
Switching element, which is a switching element, and the display element and the switch.
In series with both photoelectric conversion elements via the
Connected switching means, the display element and the photoelectric
Provided a capacitor connected in common to both conversion elements
It is characterized by: The switching means includes an image
Enables application of an image signal to the display element during display
Controls the operation, and when reading an image,
It is also possible to read the image signal from the conversion element.
It is. When the image is displayed, the capacitor
To supplement the insufficient capacity of the display element,
Image signal read from the photoelectric conversion element at the time of reading
Is used for temporary storage.
You. According to a second aspect of the present invention, there is provided the image input / output device according to the first aspect.
Wherein the photoelectric conversion element is a photodiode.
It is characterized by that.

[0007]

The switching means connected to the display element not only transmits the image signal applied to the display element, but also serves as a transmission path of the output signal when reading the output signal of the photoelectric conversion element. An image output portion formed at the center and an image output portion formed around the photoelectric conversion element are configured to have an electrically common circuit portion, so that they can be formed on the same substrate. It becomes.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An image input / output device according to the present invention will be described below with reference to FIGS. Here, FIG. 1 is a circuit diagram showing an embodiment of the image input / output device according to the present invention, and FIG. 2 is a schematic longitudinal sectional view schematically showing the structure of the image input / output device according to the present invention. First, this image input / output device
An image input / output array 1, a scanning line drive circuit 2, a data drive circuit 3, and a data read circuit 4 are main components.

In the image input / output array 1 of the present embodiment, a liquid crystal element 5 as a display element, a pixel thin film transistor 6 as a switching means connected in series to the liquid crystal element 5, and an auxiliary capacitor 7 constitute a set of output pixels. A plurality of the photo diodes 8 are arranged in a scanning direction (horizontal direction on the paper surface in FIG. 1) and a sub-scanning direction (vertical direction on the paper surface in FIG. 1). The thin film transistors 9 constitute one set of input pixels, and are provided in the same number as the output pixels in the scanning direction and the sub-scanning direction, similarly to the output pixels.

The thin-film transistor 9 for the light-receiving element constituting the input pixel has a source connected to a cathode of the photodiode 8 and a drain connected to the source of the pixel thin-film transistor 6, respectively. Incidentally, the photodiode 8 is
Any of a so-called sandwich type and a planar type may be used. In this image input / output array 1, the gate electrodes of the pixel thin film transistors 6 in the same main scanning direction are commonly connected by a gate wiring 14, and both are connected to the scanning line drive circuit 2. The drains of the pixel thin film transistors 6 in the same sub-scanning direction are connected to a common data line 20, and one end of the line 20 is connected to the switching thin film transistor 10 of the data drive circuit 3.
The other end is connected to the drain of a thin film transistor 11 for selecting a data read circuit provided in the image input / output array 1.

The source side of the data reading circuit selecting thin film transistor 11 is connected to the data reading circuit 4 and to one end of the grounded storage capacitor CL.
In the image input / output array 1, the anodes and the auxiliary capacitors 7 of all the photodiodes 8 are connected to a common bias line 12, and a constant voltage is constantly applied to the bias line 12. It has become so. Further, the gate electrodes of the light-receiving element thin film transistors 9 in the same scanning direction are connected to a common input / output selection line 13, and the light-receiving element thin film transistor 9 is externally operated on the input / output selection line 13. When the state is set, a gate signal is applied.

The scanning line drive circuit 2 has a gate
The gate line 14 is sequentially selected in the sub-scanning direction, and outputs a gate signal for activating the pixel thin film transistor 6. In this embodiment, the shift register 15 and a plurality of buffers 16 are provided. Things. The data drive circuit 3 outputs pixel data to the liquid crystal element 5. In the present embodiment, the data drive circuit 3 includes a shift register 17, a multiplexer 18, a plurality of buffers 19, and a plurality of switching thin film transistors 10. And In this data drive circuit 3, the plurality of switching thin film transistors 10 have their gate electrodes connected together by a common wiring so that a switching pulse is input from the outside. Then, when this switching pulse is input,
The plurality of switching thin film transistors 10 are simultaneously turned on.

The data read circuit 4 includes the image input / output array 1
Is read out to the outside as image data, and a voltage follower circuit 22 comprising an operational amplifier is provided.
Are provided as many as the number of pixels of the image input / output array 1 in the sub-scanning direction. The input terminal of the voltage follower circuit 22 is connected to the storage capacitor CL of the image input / output array 1 and has a read switch SWi (i = 1 to N).
Is connected to one end. Then, this read switch S
The other end of Wi (i = 1 to N) is grounded, and when the read switch SWi (i = 1 to N) is opened, the voltage follower circuit 22 is stored in the storage capacitor CL. The potential is output. Note that this read switch SW
i (i = 1 to N) are set to be in an open state for a predetermined time from a closed state one by one by a control circuit (not shown).

FIG. 2 shows an example of the structure of the image input / output device. In this image input / output device, the lower transparent substrate 23
A poly-Si layer 24, a gate insulating film 25, a gate electrode 27, and an interlayer insulating film 28 are disposed thereon to form a light-receiving element thin film transistor 9, and a transparent metal film is formed on the gate insulating film 25. 26, an a-Si layer 29 and a metal wiring 30 are arranged to form a photodiode 8. Further, the thin film transistor 9 for the light receiving element and the photodiode 8
Is provided, and a pixel reflection electrode 32 is provided on the interlayer insulating film 31 (upward in FIG. 2). On the other hand, the upper substrate 3
3 is provided with an upper transparent electrode 34 on the surface side facing the pixel reflective electrode 32, and a liquid crystal member (not shown) is sealed between the upper transparent electrode 34 and the pixel reflective electrode 32. A liquid crystal element 5 is formed.

In this configuration, the reflected light from the original (not shown) enters from the lower surface side of the lower transparent substrate 23 (see the white arrow in FIG. 2), and the photodiode 8
Is received. At this time, light leaking from the upper part (upward in FIG. 2) toward the photodiode 8 is shielded by the pixel reflective electrode 32.
It does not affect the light incident on the photodiode 8 from the lower surface side of the lower transparent substrate 23. Although polycrystalline silicon was used to form the light-receiving element thin film transistor 9, the present invention is not limited to this. Of course, amorphous silicon or single-crystal silicon may be used.

Next, the operation of the present apparatus having the above configuration will be described. First, a case where the present device operates as a liquid crystal display will be described. First, as a precondition, the image data to be displayed is stored in the data driving circuit 3.
Is input to the multiplexer 18 in advance from an external circuit. Under this assumption, when the switching pulse is input from an external circuit (not shown), the plurality of switching thin film transistors 10 are simultaneously turned on, and the first
Image data for the line L ₁ is output to the data wiring 20. Subsequently, the scanning line driving circuit 2 outputs the first
Gate in the position of the line L ₁ - DOO wiring 14 connected to connections are via a buffer 16 and has been being the pixel TFT 6 gate - gate electrode to gate - G Voltage is applied. The pixel thin film transistor 6 is turned on by the application of the gate voltage, and the image signal previously applied to the data line 20 is stored in the liquid crystal element 5 and the auxiliary capacitor 7 via the pixel thin film transistor 6. It will be.

Next, de - the shift register 17 of the motor drive circuit 3, second line L ₂ minutes image data of - after data has been entered, de through multiplexer 18 - image de the data lines 20 - data Is output. Of the scanning line driving circuit 2 of the buffer 16, the gate of the pixel TFT 6 connected through only buffer 16 at the position of the second line L ₂ - G Voltage is applied - gate to gate electrode
When the thin film transistor 6 is turned on, the image data previously applied to the data line 20 is applied to the liquid crystal element 5 and the auxiliary capacitor 7 via the pixel thin film transistor 6.
Will be accumulated. Hereinafter, a gate from the buffer 16 sequentially by scanning line driver 2 - by G Voltage is output, the image on the LCD device 5 of the third line L ₃ or later - data is to be applied in sequence.

Next, a case where the present apparatus is operated as an image reading apparatus will be described. First, the switching thin film transistor 10 is turned off by an external circuit (not shown), and the data drive circuit 3 is disconnected. The input / output selection line line 13 is connected to the gate electrode of each thin-film transistor 9 for a light receiving element.
During operation of this apparatus as an image reading apparatus, a constant voltage is applied to make the thin film transistor 9 for each light receiving element always in a conductive state, and the data reading circuit 4 is connected. In this state, each photodiode
When light reflected from a document (not shown) is input to the photodiode 8, a current corresponding to the amount of incident light flows through the photodiode 8, and electric charges are accumulated in the auxiliary capacitor 7.

[0019] Then, by the device operating the respective buffers 16 likewise scanning line driving circuit 2 as that described in the case of operating as a liquid crystal display sequentially, each pixel TFT 6 is in the first line L ₁ The conduction state is set in order from the ones. When the pixel thin film transistor 6 is turned on, each data line 20 has a potential corresponding to the electric charge stored in the auxiliary capacitance 7. Further, by applying a gate voltage to the gate electrode of the data readout circuit selecting thin film transistor 11, each storage capacitor CL is connected to the data line 20 via the data readout circuit selecting thin film transistor 11. They will be connected at the same time. The potentials accumulated in the storage capacitor CL are stored in the data read circuit 4 as image signals by sequentially opening the respective read switches SWi (i = 1 to N) of the data read circuit 4 for a predetermined time. Will be output. Hereinafter, similarly to the scanning line driving circuit 2 second line L ₂ and subsequent photodiodes - de 8 Karade - it is sufficient to read out the image signal through the data reading circuit 4.

[0020]

[0021]

As described above, according to the present invention,
By configuring the display element and the photoelectric conversion element so that a part of an electric circuit can be shared, an image input / output portion including these two elements can be provided on the same substrate, so that a small and lightweight image is obtained. This has an effect that an input / output device can be provided.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing an embodiment of an image input / output device according to the present invention.

FIG. 2 is a schematic longitudinal sectional view schematically showing the structure of the image input / output device according to the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Image input / output array, 2 ... Scanning line drive circuit, 3 ... Data drive circuit, 4 ... Data readout circuit, 6 ... Pixel thin film transistor, 9 ... Thin film transistor for light receiving element, 10 ... Thin film transistor for switching,
11 ... Thin film transistor for selecting a data read circuit, 12
... bias line, 13 ... input / output selection line, 14 ... gate wiring, 20 ... data wiring, 23 ... lower transparent substrate, 2
4: Poly-Si layer

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-5-121715 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04N 1 / 028,1 / 036,1 / 04

Claims (2)

(57) [Claims] 1. An image input / output device comprising a plurality of display elements and a plurality of photoelectric conversion elements arranged in a matrix and connected in series with said photoelectric conversion elements and turned on when reading an image.
Switching element, and an image signal can be applied to the display element when displaying an image.
While controlling the operation of
Image signal from the photoelectric conversion element
Photoelectric conversion via the display element and the switching element.
Switching means connected in series to both switching elements
Steps and auxiliary for compensating for the insufficient capacity of the display element when displaying images
When reading an image, the photoelectric conversion element
Temporary storage for temporarily storing image signals read from
Therefore, both the display element and the photoelectric conversion element are shared.
An image input / output device comprising a capacitor connected to the image input device. 2. The photoelectric conversion element is a photodiode.
The image input / output device according to claim 1.