JP2004102260A - Active matrix display inspection method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid cell and its inspection method for effectively inspecting the image quality of the liquid cell before a driver IC is connected. <P>SOLUTION: This liquid cell has an inspection circuit 4 and 5. The inspection circuit has scanning signal wires 11 or inspection TFTs 22 connected to data signal wires 12, inspection terminals 31-35 connected to the scanning signal wires 11, and inspection terminals 41-53 connected to data signal wires 12. A plurality of inspection TFTs 22 are connected to the inspection terminals. A display region is divided into a plurality of blocks, and a set of scanning side inspection terminals and a set of data signal side inspection terminals are connected to every block. Scanning signal wires and data signal wires of a specific region are assigned to every block. Since a plurality of signal wires are suitably collected by the inspection TFTs and inspection terminals, necessary image quality inspection can be performed without using multi-pin probes. <P>COPYRIGHT: (C)2004,JPO

Description

The present invention relates to an active matrix display device and a method for testing the same, and more particularly, to an active matrix display device having a circuit for testing a display device and a method for testing the same.

The manufacturing process of TFT color liquid crystal display devices, which are now widely used, can be broadly divided into a manufacturing process of a liquid crystal cell, a manufacturing process of a liquid crystal module, and a manufacturing process of a liquid crystal monitor. The liquid crystal module is completed by connecting a driver IC to a liquid crystal cell and a drive circuit for generating a control signal to be input to the liquid crystal cell, and mounting a backlight and mechanical components. Further, a graphic adapter for generating a signal including image information to be input is connected to the liquid crystal module, and a mechanical component is mounted thereon, whereby a liquid crystal monitor is completed.

製造 In the manufacture of liquid crystal display devices, it is necessary to find defects resulting from contamination and dimensional errors in the manufacturing process at an early stage in order to increase the manufacturing efficiency. For this reason, various inspections such as a gap inspection and a lighting inspection are performed in each stage of the manufacturing process of the liquid crystal display device.

For example, Japanese Patent Application Laid-Open No. 60-2989 discloses a method for detecting disconnection / short-circuit of data / scanning lines of a TFT array. In a liquid crystal display device having only one X drive circuit, disconnection of data / scan lines can be detected. By providing a group of inspection transistors on the opposite side of the X drive circuit, disconnection of data / scan lines can be achieved.・ A short circuit has been detected. Specifically, the inspection is performed by outputting a specific inspection signal input from the driving circuit from the inspection transistor.

In addition, in JP-A-3-18891, 3-20721, 5-5897, and 5-11000, a signal line for inspection or a switching circuit is connected to an active matrix array on the opposite side of a drive circuit. In addition, it is disclosed that the inspection of the array is performed. Japanese Patent Application Laid-Open No. 2-154292 discloses that an active matrix array is inspected for disconnection using a selection circuit having an analog switch function before connecting a driving IC.

一 つ One of these inspections is an image quality inspection performed after a TFT liquid crystal cell is completed. There are various known image quality inspection methods for a TFT liquid crystal cell, but an inspection method called a multi-pin probe method is mainly performed.

This is because in the final step of manufacturing the liquid crystal cell, each signal input terminal of the liquid crystal cell is individually contacted with a probe by a probe, and an electric signal equivalent to an input signal from a driver IC in the liquid crystal module is input. Done. This makes it possible to completely reproduce the driving of the liquid crystal cell in the final product, so that the inspection can be performed by visually checking the display screen of the final product. In this case, all types of screens can be displayed by preparing input signals. However, the inspection using the multi-pin probe method has several problems described below.

First, multi-pin probes are expensive and require a lot of time to manufacture. For example, a liquid crystal cell having 1024 pixels (× 3 sub-pixels) × 768 rows has at least 3840 lines to which signals are to be input. A probe must be provided that can be contacted.

There is also a problem with the stability of the inspection. In recent years, as the size and resolution of liquid crystal cells have increased, the number of probes has been increasing and the density has been increasing. Therefore, instability of electrical contact of the probes has become a problem. When the electrical contact becomes unstable, the inspection screen is not displayed along the wiring to which a signal to be input is not given, and the inspection efficiency is significantly reduced. This is fatal when performing an automatic inspection by image processing or the like. Further, as the resolution of the liquid crystal cell becomes higher, the distance between adjacent probes becomes smaller, so that not only the test stability is lowered but also the probe itself is reaching its limit.

Additionally, the multi-pin probe cannot cope with many kinds of products, resulting in an increase in cost and a decrease in inspection efficiency. This is because it is difficult to standardize the probe arrangement between different types of liquid crystal cells when manufacturing multiple types of liquid crystal cells due to differences in the specifications of each type, so it is necessary to prepare a probe set for each type and replace it with an inspection device. It is.

From the above, there is a demand for an inspection method that does not require the use of a multi-pin probe even if the types of inspection screens that can be displayed are limited.
JP-A-60-2989 JP-A-3-18891 JP-A-3-20721 JP-A-5-5897 JP-A-5-11000 JP-A-2-154292

An object of the present invention is to provide a display device and an inspection method for the display device, which can efficiently perform an image quality inspection.
It is another object of the present invention to provide a display device having an inspection circuit capable of coping with many image quality inspections, and an inspection method thereof.
Another object of the present invention is to provide a display device and a method for inspecting the display device, which can surely inspect the display device.
It is another object of the present invention to provide an apparatus and a method for inspecting a large and high-definition display device that can be stably inspected.
It is another object of the present invention to provide a display device and an inspection method thereof, which can efficiently perform an image quality inspection of a display device before a driver IC is connected.

The active matrix display device according to the present invention has an inspection circuit for performing an image quality inspection. The test circuit includes a plurality of input terminals for inputting a test signal, and a plurality of test transistors connected to each input terminal. A desired inspection screen is displayed by input-controlling an input inspection signal sent from the input terminal to the sub-pixel unit by the inspection transistor. The test transistor is preferably an amorphous silicon TFT.

入 力 A plurality of inspection transistors are connected to one input terminal. Preferably, all gate electrodes of the test transistor are connected to one input terminal. Another input terminal is connected to the source electrode of the test transistor. Preferably, the test transistors connected to adjacent sub-pixel unit columns are connected to different input terminals. Further, the test transistors connected to the sub-pixel unit columns of different colors are connected to different input terminals.

It is preferable that the inspection circuit is formed on both the data signal wiring side and the scanning signal wiring side. More preferably, the inspection circuit on one side includes at least three input terminals. One of them is connected to the gate electrodes of all the test transistors, and the other two terminals are connected to the test TFTs connected to the adjacent sub-pixel unit column so that they are alternately connected to other terminals. Is done. The other test circuit has at least seven input terminals. The gates of all the inspection TFTs are connected to one terminal. As for the other terminals, the test TFTs connected to the sub-pixel columns having different colors of RGB are connected to different terminals. In addition, the inspection TFTs connected to adjacent sub-pixel unit columns are connected to different terminals. In other words, there are a total of six terminals including an odd-numbered sub-pixel row and three terminals for each of the RGB colors, an even-numbered sub-pixel row, and three terminals for each of the RGB colors. .

An array substrate in which sub-pixel portions having switching elements are arranged in a matrix, and a counter substrate facing the array substrate, comprising:
The array substrate,
A plurality of data signal lines and a plurality of scanning signal lines for sending a signal to the sub-pixel portion,
A test transistor connected to each of the plurality of data signal lines,
A plurality of input terminals for inputting inspection signals;
Has,
A drain or a source of the inspection transistor is connected to the data signal line,
The gates of the plurality of test transistors are connected to a first input terminal of the plurality of input terminals,
A source or a drain of the plurality of test transistors is connected to a second input terminal of the plurality of input terminals,
The inspection transistor controls input of an inspection signal to the sub-pixel unit.

Liquid crystal cell.
FIG. 1 is a schematic diagram showing the entire structure of the liquid crystal cell in the present embodiment. In the figure, 1 is a liquid crystal cell, 2 is a TFT array substrate, and 3 is a counter substrate arranged in parallel with the TFT array substrate 2. Although not shown here, liquid crystal is sealed between the TFT array substrate 2 and the counter substrate 3 with a sealing material and a sealing resin. The liquid crystal cell is provided with an alignment film, a transfer, a polarizing film, and the like, and the distance between the two substrates is maintained by spacer balls provided therebetween. In this embodiment, the counter substrate 3 is a color filter substrate on which RGB color filters are formed.

The alignment film is formed on each of the two substrates so as to determine the initial alignment of the liquid crystal. The sealant is formed outside the display pixel region 7 in order to adhere the two substrates and confine the liquid crystal between the substrates. In addition, the sealing resin is formed to inject liquid crystal between the two substrates from a pre-provided non-forming region of a sealing material called an injection port and then seal the liquid crystal. Spacer balls are spherical insulators for determining the gap between two substrates and are scattered on one of the substrates. The transfer formed outside the display pixel area 7 is a conductive substance for giving the common electrode potential input from the terminal on the TFT array substrate 2 to the common electrode on the counter substrate 3. A polarizing film is formed on each of the outer surfaces of the two substrates bonded together, and controls the polarization of light entering the liquid crystal cell.

In FIG. 1, reference numerals 4 and 5 denote inspection circuits for inspecting the image quality of the liquid crystal cell. These are formed on the TFT array substrate 2. Reference numeral 7 denotes a display area in which display is actually performed in the liquid crystal cell. Reference numeral 6 denotes an outer peripheral area of the display area, in which a display signal input terminal 16 to which a driver IC for inputting a screen display signal is connected is formed.

TFT array circuit.
FIG. 2 is a schematic diagram showing a circuit structure of the TFT array substrate 2. In the drawing, reference numeral 11 denotes a plurality of scanning signal wirings extending in one direction in parallel with each other and to which a scanning signal is supplied, and 12 extends in parallel to each other in a direction intersecting with the scanning signal wirings 11 to supply a video signal. A plurality of data signal wirings 12. The TFT array substrate 2 includes a plurality of sub-pixels 13 arranged in a matrix in a display pixel area 7, and each sub-pixel 13 is surrounded by a scanning signal line 11 and a data signal line 12. Each sub-pixel 13 includes a pixel electrode 15 (ITO film) for applying an electric field to the liquid crystal, an additional capacitor (Cs) 18 for complementing the holding capability of the pixel electrode, and a scanning signal line 11 and a signal line 12. And a thin film transistor (TFT) 14 having a switching function. Outside the display area 7, circuits 4 and 5 for inspecting the image quality of the liquid crystal cell, display signal input terminals 16 for inputting electric signals to the wirings 11 and 12, and the like are formed. The structures of the image quality inspection circuits 4 and 5 will be described later in detail.

On the color filter substrate 3 (not shown), a color filter for separating the three primary colors of RGB, a common electrode 17 for controlling the orientation of the liquid crystal by an electric field between the pixel electrode 15 on the TFT array substrate 2, and the like. Is formed. Each sub-pixel has one of RGB color filters. The display of the liquid crystal cell can be performed by controlling the orientation of the enclosed liquid crystal by the potential difference between each pixel electrode 15 and the common electrode 17. This potential difference control is performed by manipulating a signal input by the TFT 14. Done in The amount of light transmitted through the liquid crystal cell is controlled by the orientation of the liquid crystal. Note that three sub-pixels of RGB form one pixel.

In the present embodiment, the TFT 14 is formed of amorphous silicon, and the inspection circuits 4 and 5 also include an amorphous silicon TFT. Therefore, the inspection circuits 4 and 5 can be formed simultaneously with the TFT 14 by adding a pattern on the photomask. In addition, the wiring of the inspection circuits 4 and 5 and the inspection terminal can be formed simultaneously with the wiring of the liquid crystal display circuit and the display signal input terminal 16. As a result, no additional manufacturing steps are required for forming the inspection circuits 4 and 5. Although the manufacturing process of the TFT array substrate is performed by using a deposition and etching process using a photoresist, these are widely known techniques, and will not be described in detail here.

Inspection circuit.
The inspection circuits 4 and 5 will be described. FIG. 2 is a circuit diagram schematically showing a circuit formed on the TFT array substrate 2 in the present embodiment. It should be noted that the figure shows only a partial structure of the circuit for convenience of explanation, and does not show the entire structure. In the figure, reference numeral 22 denotes a scanning signal wiring or an inspection TFT connected to each signal wiring, and has a source electrode 23, a drain electrode 24, and a gate electrode 25. 31 to 35 are inspection terminals connected to the scanning signal wiring 11, and 41 to 53 are inspection terminals connected to the signal wiring 12. There are a total of 18 types of test input signals to be applied to this circuit, 5 types on the scanning signal wiring side and 13 types on the signal wiring side.

The display area is divided into a plurality of blocks, and one set of scanning-side inspection terminals and one set of signal-side inspection terminals are connected to each block. A scanning signal wiring and a signal wiring of a specific area are assigned to each block. The test terminals 31 and 32 and the test terminals 33 and 34 form one set, respectively, and are connected to the source 23 of the test TFT. The inspection terminal 35 is connected to the gates 25 of all the scanning-side inspection TFTs. The test terminals 41 to 46 and 47 to 52 each constitute one set, and are connected to the source 23 of the test TFT via a common source line. The inspection terminal 53 is connected to the gates 25 of all the signal-side inspection TFTs and to a common gate wiring. It goes without saying that the source and the drain can be reversed.

(4) The inspection terminals 31 to 35 on the scanning signal wiring side are connected as follows. The inspection terminals 31 and 32 are alternately connected to the scanning signal wiring 11 in the region 61 corresponding to a certain block via the inspection TFT 22. That is, the inspection terminal 31 is connected to the (2m + 1) -th area 61, and the inspection terminal 32 is connected to the (2m + 2) -th area (m is an integer) in the area 61.

Similarly, the inspection terminals 33 and 34 are alternately connected to the scanning signal wiring 11 in an area 62 different from the upper area 61 via the inspection TFT 22. That is, the inspection terminal 33 is connected to the (2n + 1) -th line of the region 62, and the inspection terminal 34 is connected to the (2n + 2) -th line (n is an integer) of the region 61. Although each region includes only four sub-pixel columns in the drawing, in reality, more sub-pixel rows are included in one region.

(4) By configuring the scanning line side inspection circuit 5 as described above, it is possible to select an odd-numbered scanning signal wiring and an even-numbered scanning signal wiring of each block at different timings and to input an inspection signal. As a result, a row inversion (row inversion) drive or a pixel inversion (dot inversion) drive, which is a type of a method of AC driving by inverting the polarity of the voltage applied to the liquid crystal for each frame by a potential input to the signal wiring, for each frame. Can also be handled. Note that even if the odd-numbered and even-numbered scanning signal lines are selected at the same time, frame inversion driving can be performed by inverting the potential input to the signal lines for each frame.

{Circle around (1)} By such a connection method, the scanning signal wirings of the region 61 and the region 62 can be selected at different timings. As a result, different patterns can be displayed in the region 61 and the region 62 on the display screen depending on the potential input to the signal wiring.

(1) The set of inspection terminals 41 to 53 on the signal wiring side are connected as follows. The inspection terminals 41 and 42 are connected to the (6p + 1) -th and (6p + 4) -th (p is an integer) signal wiring 12 of the certain region 63 via the inspection TFT 22, respectively. At this time, the inspection terminals 41 and 42 are connected to the source electrode 23 of the inspection TFT 22, and the signal wiring 12 is connected to the drain electrode 24. It goes without saying that the source and the drain can be reversed.

The inspection terminals 43 and 44 are connected to the (6p + 5) th and (6p + 2) th (p is an integer) of the signal wiring 12 in the region 63 via the inspection TFT 22, respectively. At this time, the inspection terminals 43 and 44 are connected to the source electrode 23 of the inspection TFT 22, and the signal wiring 12 is connected to the drain electrode 24. The inspection terminals 45 and 46 are connected to the (6p + 3) -th and (6p + 6) -th (p is an integer) of the signal wiring 12 in the region 63 via the inspection TFT 22, respectively. At this time, the inspection terminals 45 and 46 are connected to the source electrode 23 of the inspection TFT 22, and the signal wiring 12 is connected to the drain electrode 24.

Another set of inspection terminals 47 to 52 on the signal wiring side is connected to the signal wiring 12 in an area 64 different from the upper area 63. The inspection terminals 47 and 48 are connected to the (6q + 4) -th and (6q + 1) -th (q is an integer) of the signal wiring 12 in the region 64 via the inspection TFT 22, respectively. At this time, the inspection terminals 47 and 48 are connected to the source electrode 23 of the inspection TFT 22, and the signal wiring 12 is connected to the drain electrode 24.

The inspection terminals 49 and 50 are connected to the (6q + 2) -th and (6q + 5) -th (q is an integer) of the signal wiring 12 in the region 64 via the inspection TFT 22, respectively. At this time, the inspection terminals 49 and 50 are connected to the source electrode 23 of the inspection TFT 22, and the signal wiring 12 is connected to the drain electrode 24. The inspection terminals 51 and 52 are connected to the (6q + 6) th and (6q + 3) th (q is an integer) of the signal wiring 12 in the region 64 via the inspection TFT 22, respectively. At this time, the test terminals 51 and 52 are connected to the source electrode 23 of the test TFT 22, and the signal wiring 12 is connected to the drain electrode 24. In the figure, each region has only four sub-pixel columns, but actually has more continuous sub-pixel columns.

液晶 The liquid crystal cell 1 of this embodiment has RGB sub-pixels arranged in a vertical stripe. That is, the sub-pixel columns (the columns in the vertical direction in FIG. 2) defined by the signal lines sequentially have the RGB color filters. By configuring the signal line side inspection circuit 4 as described above, it becomes possible to apply voltages having opposite polarities to the liquid crystal between adjacent sub-pixel columns. Further, since a voltage can be independently applied to each of the R, G, and B sub-pixel columns, an arbitrary color can be displayed in the entire display area. Further, by changing the potential applied to the signal wirings of the regions 63 and 64, different patterns can be displayed in the regions 63 and 64 on the display screen.

Image quality inspection.
An image quality inspection method for the liquid crystal cell 1 in the present embodiment will be described. In this image quality inspection, a probe that applies a scanning signal and a video data signal (video signal) to the electrode terminal 16 of the liquid crystal cell 1 to perform a picture output inspection by a conventional method of providing an inspection signal is used. Is brought into contact with the inspection terminals 31 to 35 and 41 to 53 to perform an image output inspection. A signal sent from the inspection terminal to the sub-pixel portion can be controlled by operating the inspection TFT.

FIG. 3 shows an example of a test drive waveform applied to the test circuits 4 and 5 in this embodiment. This example is an example in which a window display for inspection is displayed by pixel inversion (dot inversion) driving. This window display is shown in FIG. FIG. 3 shows only a part of the test drive signal applied. Actually, a signal having the same shape as this signal is continuously input to the liquid crystal cell 1. In FIG. 3, the horizontal axis represents the time axis. The periods T (1) and T (2) represent one frame period, and the difference between the periods T (1) and T (2) and the periods T (3) and T (4) is that the signal S (k ) And S (k + 1) are in opposite phases. These signals are repeatedly and continuously input to the liquid crystal cell 1 while one inspection screen is displayed, with these periods T (1) to T (4) as one cycle.

{Other driving examples include a row inversion (row inversion) drive and a column inversion (column inversion) drive. By changing the input signal waveform, these necessary driving methods can be easily realized. Further, by making the input signal voltage variable, an arbitrary gradation display can be performed. Also, in this example, since the R, G, and B signals can be input independently, any color display is possible.

FIG. 4 is a diagram showing a window display for inspection as an example of a display screen for inspection. The display screen is composed of a plurality of blocks. Here, how to input the signal of FIG. 3 to the circuit of FIG. 2 in order to obtain the inspection screen display of FIG. 4 will be described. The liquid crystal cell 1 is in a normally white mode.

First, the correspondence between the regions in FIGS. 2 and 4 in this example will be described. The region 61 in FIG. 2 corresponds to the region 72 in FIG. 4, and the region 62 corresponds to the region 71 and the region 73. Similarly, region 63 in FIG. 2 corresponds to region 74 and region 76 in FIG. 4, and region 64 corresponds to region 75. The blocks on the display screen are specified by these areas.

(4) The signals G (i) and G (i + 1) shown in FIG. Similarly, signals G (j) and G (j + 1) are input to terminals 32 and 31, respectively. Further, the signal S (k) is inputted to the terminals 47, 49 and 51, and the signal S (k + 1) is inputted to the terminals 48, 50 and 52 in the same manner. The signals of the signal S (k) in FIG. 3 are input to the terminals 41, 43, and 45 during the periods T (1) and T (3), and also during the periods T (2) and T (4). , A waveform having the same voltage amplitude as the periods T (1) and T (3) is input. Similarly, the signals S (k + 1) shown in FIG. 3 are input to the terminals 42, 44, and 46 during the periods T (1) and T (3), and the signals are outputted during the periods T (2) and T (4 ), A signal waveform is input such that the voltage amplitude is the same as that of the periods T (1) and T (3).

(4) When conducting a display inspection of the liquid crystal cell, a sufficiently high potential is continuously input to the terminals 35 and 53 so that the inspection TFT is always turned on. Then, as shown in FIG. 4, the display screen has a window that is black in the normally white mode liquid crystal cell in a block specified by the region 72 and the region 75 and gray in other blocks. The display is realized.

As another example of the inspection display screen, for example, it is conceivable to display the entire surface in blue (B). In FIG. 2, the sub-pixel columns continue in the order of R, G, and B from the left. Therefore, by applying a drive signal representing a bright display to the (3r) -th (r is an integer) signal wiring 12 and applying a driving signal representing a black display to the other signal wirings 12, the entire surface is displayed in blue (B). It can be performed. Specifically, a voltage (amplitude 0) having a smaller amplitude than the periods T (1) and T (3) of S (k) and S (k + 1) in FIG. 3 is applied to the terminals 45, 46, 51 and 52. To the terminals 41 to 44 and 47 to 50 by applying voltages having the same amplitude as the periods T (2) and T (4) of S (k) and S (k + 1). realizable. Similarly, monochrome display of red (R) and green (G) can be performed, and depending on the applied voltage amplitude, any intermediate color can be displayed by a combination of RGB.

When inspecting the display screen of a liquid crystal cell, if the above method is used, the display pattern required for the inspection can be displayed with a very small number of signal input terminals, and stable and low-cost inspection is realized. be able to.

After the above-described image quality inspection is performed, a driver IC and a drive circuit for generating a control signal to be input to the driver IC are connected to the liquid crystal cell, and a backlight and a mechanical component are mounted to complete a liquid crystal module. . The inspection TFT is turned off when the final product is driven. This is intended to stably disconnect the input bundled at the time of inspection.

As described above, since the present embodiment has the inspection circuit having the above-described configuration, signals required for image quality inspection can be input to the liquid crystal cell without using a multi-pin probe. Can be efficiently performed.

In this embodiment, the inspection circuit is formed on both the scanning signal wiring and the signal wiring. However, only one of the inspection circuits is provided with the inspection circuit, and the other is provided with the conventional multi-pin probe to input the inspection signal. Is also possible. For example, instead of the inspection circuit on the scanning signal wiring side, a multi-pin probe is connected.

(4) The number of input terminals can be increased or decreased according to the display screen type and the driving conditions. Specifically, in the present embodiment, the number of connection terminals connected to the signal wiring 12 is two. However, by further increasing the number of connection terminals, it is possible to perform more detailed block display. In the present embodiment, the gates of all the inspection TFTs are connected to one common gate line, but it is of course possible to divide the gates into a plurality.

Conversely, the number of input terminals may be reduced. For example, when performing only the color display inspection of the entire screen as the image quality inspection, the inspection circuit on the scanning signal wiring side is provided with only one common gate terminal and one common source terminal. In the inspection circuit on the signal wiring side, only one common source terminal for each of R, G, and B sub-pixels and only one gate terminal common to all inspection TFTs are formed. By controlling the applied voltage by this inspection circuit, at least full screen display of all colors can be performed.

In the present embodiment, the display area is divided into nine blocks. However, the number of subpixels included in each area is reduced, and each area is alternately connected to each set of connection terminals in the present embodiment. Can be divided into blocks. Increasing the number of blocks enables more detailed inspection. In the above embodiment, the source electrode 23 of the inspection TFT 22 is connected to one of a plurality of types of inspection terminals (terminals 31 to 34 or terminals 41 to 52), and the gate electrode is connected to a common inspection terminal. It is connected to a terminal (terminal 35 or 53). However, on the contrary, a configuration in which the gate electrode of the inspection TFT is connected to one of a plurality of types of inspection terminals determined by the display pattern, and the source electrode is connected to one common inspection terminal. It may be. Further, the inspection TFT may be connected to only some of the signal lines.

The test circuit of the present invention can be applied not only to a liquid crystal cell but also to a display device using other active elements and a liquid crystal display device not using a color filter. Examples of other display devices include an AM-PLED (active matrix-polymer light emitting diode) or an AM-OLED (active matrix) that controls light emission by operating a voltage applied to an organic polymer film by an active element. Self-luminous display using an organic light emitting diode).

The present invention is disclosed below as a summary.
(1) A display device comprising: an array substrate on which sub-pixel portions having switching elements are arranged in a matrix; and a counter substrate facing the array substrate,
The array substrate,
A plurality of data signal lines and a plurality of scanning signal lines for sending a signal to the sub-pixel portion,
A test transistor connected to each of the plurality of data signal lines,
A plurality of input terminals for inputting inspection signals;
Has,
A drain or a source of the inspection transistor is connected to the data signal line,
The gates of the plurality of test transistors are connected to a first input terminal of the plurality of input terminals,
A source or a drain of the plurality of test transistors is connected to a second input terminal of the plurality of input terminals,
The inspection transistor controls input of an inspection signal to the sub-pixel unit,
Active matrix display.
(2) A display device comprising: an array substrate on which sub-pixel portions having switching elements are arranged in a matrix; and a counter substrate facing the array substrate,
The array substrate,
A plurality of data signal lines and a plurality of scanning signal lines for sending a signal to the sub-pixel portion,
An inspection transistor connected to each of the plurality of scanning signal lines,
A plurality of input terminals for inputting inspection signals;
Has,
A drain or a source of the inspection transistor is connected to the scanning signal line,
The gates of the plurality of test transistors are connected to a first input terminal of the plurality of input terminals,
A source or a drain of the plurality of test transistors is connected to a second input terminal of the plurality of input terminals,
The inspection transistor controls input of an inspection signal to the sub-pixel unit,
Active matrix display.
(3) The active matrix display device according to (1) or (2), wherein the switching element of the sub-pixel unit and the inspection transistor are TFTs formed of amorphous silicon.
(4) Each of the sub-pixel units can display one color,
The active matrix display device according to (1) or (2), wherein all of the plurality of inspection transistors connected to the second input terminal are connected to a sub-pixel portion of the same color.
(5) Each of the sub-pixel units can display one color,
The active matrix display device according to (1) or (2), wherein all of the plurality of test transistors connected to the first input terminal are connected to a sub-pixel portion of the same color.
(6) The active transistor according to (1) or (4), wherein a source or a drain of the test transistor connected to the adjacent data signal line is connected to a different one of the plurality of input terminals. Matrix display device.
(7) The active transistor according to (2) or (4), wherein a source or a drain of the inspection transistor connected to the adjacent scanning signal line is connected to a different one of the plurality of input terminals. Matrix display device.
(8) The active matrix display device according to (1), wherein the gates of all the test transistors connected to the data signal lines on the array substrate are connected to the first input terminal.
(9) The active matrix display device according to (2), wherein the gates of all the test transistors connected to the scan signal lines on the array substrate are connected to the first input terminal.
(10) Each of the sub-pixel units can display one color,
All of the plurality of test transistors connected to the second input terminal are connected to a sub-pixel portion of the same color,
The gates of all the test transistors connected to the data signal lines on the array substrate are connected to the first input terminal,
The active matrix display device according to (1), wherein a source or a drain of the test transistor connected to the adjacent data signal line is connected to a different one of the plurality of input terminals.
(11) The array substrate further comprises:
A scanning line inspection transistor connected to each of the plurality of scanning signal lines,
A plurality of scanning line input terminals for inputting inspection signals to the scanning lines,
Has,
A drain or a source of the scanning line inspection transistor is connected to the scanning signal line,
Gates of the plurality of scanning line inspection transistors are connected to a first scanning line input terminal of the plurality of scanning line input terminals,
A source or a drain of the plurality of scanning line inspection transistors is connected to a second scanning line input terminal among the plurality of scanning line input terminals,
The active matrix display device according to (1), wherein the scanning line inspection transistor controls input of an inspection signal to the sub-pixel unit.
(12) The source according to (10), wherein a source or a drain of the scanning line inspection transistor connected to the adjacent scanning signal line is connected to a different scanning line input terminal among the plurality of scanning line input terminals. Active matrix display.
(13) The active matrix display device further includes a driving circuit connected to the plurality of data signal lines and the plurality of scanning signal lines,
The active matrix display device according to (1) or (2), wherein when the drive circuit controls the input of a screen display signal, all the check transistors are maintained in an OFF state.
(14) An image quality inspection method for an active matrix display device including: an array substrate on which sub-pixel portions having switching elements are arranged in a matrix; and a counter substrate facing the array substrate.
A first step of inputting a test signal from a first input terminal;
A second step of inputting a test signal from a second input terminal;
A third step of sending the input test signal to source electrodes of a first plurality of test transistors connected to the first input terminal;
A fourth step of sending the input test signal to a gate electrode of the first plurality of test transistors connected to the second input terminal;
A fifth step of sending the inspection signal from the plurality of inspection transistors to the sub-pixel unit via a data signal line connected to each of the plurality of inspection transistors;
Has,
An image quality inspection method for displaying a desired display screen by controlling the input of the inspection signal to a sub-pixel by the plurality of inspection transistors.
(15) An image quality inspection method for an active matrix display device including: an array substrate on which sub-pixel units having switching elements are arranged in a matrix; and a counter substrate facing the array substrate.
A first step of inputting a test signal from an input terminal;
Sending the input test signal to a plurality of test transistors connected to the input terminal; and
A third step of transmitting the inspection signal from the plurality of inspection TFTs to the sub-pixel unit via a scanning signal line connected to each of the plurality of inspection transistors;
Has,
An image quality inspection method for displaying a desired display screen by controlling the input of the inspection signal to the sub-pixel by the inspection transistor.

FIG. 2 is a schematic diagram illustrating a configuration of a liquid crystal cell according to the present embodiment. 3 is a schematic diagram showing a circuit structure of a liquid crystal cell in the present embodiment. FIG. 3 is a schematic diagram showing an image quality inspection signal in the present embodiment. FIG. 3 is a schematic diagram showing an inspection screen in the present embodiment.

Explanation of reference numerals

REFERENCE SIGNS LIST 1 liquid crystal cell 2 TFT array substrate 3 color filter substrate 4, 5 inspection circuit 6 outer peripheral area 7 display area 11 scanning signal wiring 12 data signal wiring 13 subpixel 15 pixel electrode (ITO film)
18 Additional capacity (Cs)
22 Inspection TFT
23 Source electrode 24 Drain electrode 25 Gate electrode 31-35 Inspection terminal 41-53 Inspection terminal

Claims (7)

An array substrate in which sub-pixel portions having switching elements are arranged in a matrix, and a counter substrate facing the array substrate, comprising:
The array substrate,
A plurality of data signal lines and a plurality of scanning signal lines for sending a signal to the sub-pixel portion,
A test transistor connected to each of the plurality of data signal lines,
A plurality of input terminals for inputting inspection signals;
Has,
A drain or a source of the inspection transistor is connected to the data signal line,
The gates of the plurality of test transistors are connected to a first input terminal of the plurality of input terminals,
A source or a drain of the plurality of test transistors is connected to a second input terminal of the plurality of input terminals,
The inspection transistor controls input of an inspection signal to the sub-pixel unit,
Active matrix display. An array substrate in which sub-pixel portions having switching elements are arranged in a matrix, and a counter substrate facing the array substrate, comprising:
The array substrate,
A plurality of data signal lines and a plurality of scanning signal lines for sending a signal to the sub-pixel portion,
An inspection transistor connected to each of the plurality of scanning signal lines,
A plurality of input terminals for inputting inspection signals;
Has,
A drain or a source of the inspection transistor is connected to the scanning signal line,
The gates of the plurality of test transistors are connected to a first input terminal of the plurality of input terminals,
A source or a drain of the plurality of test transistors is connected to a second input terminal of the plurality of input terminals,
The inspection transistor controls input of an inspection signal to the sub-pixel unit,
Active matrix display. 3. The active matrix display device according to claim 1, wherein the switching element of the sub-pixel unit and the inspection transistor are TFTs formed of amorphous silicon. Each of the sub-pixel units can display one color,
3. The active matrix display device according to claim 1, wherein all of the plurality of test transistors connected to the second input terminal are connected to a sub-pixel unit of the same color. An array substrate in which sub-pixel portions having switching elements are arranged in a matrix, and a counter substrate facing the array substrate, an image quality inspection method for an active matrix display device,
A first step of inputting a test signal from a first input terminal;
A second step of inputting a test signal from a second input terminal;
A third step of sending the input test signal to source electrodes of a first plurality of test transistors connected to the first input terminal;
A fourth step of sending the input test signal to a gate electrode of the first plurality of test transistors connected to the second input terminal;
A fifth step of sending the inspection signal from the plurality of inspection transistors to the sub-pixel unit via a data signal line connected to each of the plurality of inspection transistors;
Has,
An image quality inspection method for displaying a desired display screen by controlling the input of the inspection signal to the sub-pixel by the plurality of inspection transistors. An array substrate in which sub-pixel portions having switching elements are arranged in a matrix, and a counter substrate facing the array substrate, an image quality inspection method for an active matrix display device,
A first step of inputting a test signal from an input terminal;
A second step of sending the input test signal to a plurality of test transistors connected to the input terminal;
A third step of transmitting the inspection signal from the plurality of inspection TFTs to the sub-pixel unit via a scanning signal line connected to each of the plurality of inspection transistors;
Has,
An image quality inspection method for displaying a desired display screen by controlling the input of the inspection signal to the sub-pixel by the inspection transistor. The image quality inspection method according to claim 14, wherein in the fifth step, an inspection signal is sent to a sub-pixel unit that displays the same color.

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