JP2003228298A - Image display panel member, image display panel, method of manufacturing image display panel, image display device - Google Patents

Abstract

(57) Abstract: An image display panel on which a drive circuit is mounted, without using an external inspection signal output means, displays the image panel before mounting the drive circuit. SOLUTION: A glass substrate 11 and a plurality of gate wirings 1 are provided.
2, the plurality of source wirings 13, the plurality of pixel driving electrodes connected to the gate wiring 12 and the source wiring 13, the scanning-side driving signal lines 21a and 21b, and the image-side driving signal lines 22a to 22c. In the image display panel member, the scanning-side switching element 23a and the connection line 28a for connecting the gate line 12 and the scanning-side drive signal lines 21a and 21b, the source line 13 and the image-side drive signal line 22
and at least one of an image-side switching element 23b and a connection wiring 28b for connecting a to c,
A scanning-side driving signal or a gate inspection signal is supplied to the scanning-side driving wiring, and an image-side driving signal or a source inspection signal is supplied to the image-side driving wiring.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to the structure of an image display panel such as a liquid crystal panel.

[0002]

2. Description of the Related Art Liquid crystal panels have the advantages of small size, light weight, and low power consumption, and are widely used as monitors for notebook PCs and car navigation systems. Above all, an active matrix type TFT liquid crystal panel excellent in contrast and response speed is widely used.

An example of this liquid crystal panel is shown in FIG. In the figure, 11 is a glass substrate, 12 is a gate wiring, 13 is a source wiring, and 14 is a pixel electrode. A switching element 15 is connected to the gate line 12, the source line 13, and the pixel electrode 14, and electrically connects / disconnects the source line 13 and the pixel electrode 14. Reference numeral 16 denotes a gate wiring driving circuit for the gate wiring 12, and 17 denotes a source wiring driving circuit for the source wiring 13, which uses a semiconductor IC. The drive signals of the gate line drive circuit 16 and the source line drive circuit 17 are created by the external circuit 18, and are supplied to the input terminals of the gate line drive circuit 16 and the source line drive circuit 17 via the line 19, respectively.

Although not shown in the figure, the glass substrate 11 has a structure facing the counter electrode with the liquid crystal interposed therebetween.

[0005]

In order to inspect whether this liquid crystal panel operates normally, it is necessary to connect the gate wiring drive circuit 16 and the source wiring drive circuit 17 to display the liquid crystal panel. When a display defect occurs, it is difficult to determine whether the cause is the gate wiring drive circuit 16 and the source wiring drive circuit 17 or the display panel side.

Therefore, during the inspection of the liquid crystal panel, the liquid crystal panel is displayed before the semiconductor IC, which is the gate wiring drive circuit 16 for the gate wiring 12 and the source wiring drive circuit 17 for the source wiring 13, is mounted. It is desirable to inspect for line defects and point defects.

However, for this purpose, a wiring for inspection in which a plurality of gate wirings 12 and source wirings 13 are connected,
And it is necessary to add a device for inputting a signal for inspection from the outside. Further, there is a problem that the size of the liquid crystal panel becomes large when the wiring is added.

The present invention has been made in view of the above problems, and it is possible to perform a display inspection without using an external inspection signal output device and to reduce the size of a liquid crystal panel. An object is to provide a member, a method for manufacturing an image display panel, an image display panel, and an image display device.

[0009]

In order to achieve the above object, a first aspect of the present invention (corresponding to claim 1) is a substrate, a plurality of gate wirings provided on the substrate, and the substrate. A plurality of source wirings provided above and intersecting the plurality of gate wirings in a matrix, a plurality of pixel driving electrodes connected to the gate wirings and the source wirings, and a scanning signal to the gate wirings. A scanning side drive signal wiring for supplying a scanning side drive signal to the scanning line drive circuit for outputting, and an image side drive signal for supplying an image side drive signal to the image line drive circuit for outputting an image signal to the source wiring In an image display panel member having wiring, an image connecting the scanning side bypass wiring connecting the gate wiring and the scanning side drive signal wiring, and the source wiring and the image side drive signal wiring At least one of the bypass wirings is provided, the scanning side driving signal is supplied with the scanning side driving signal or the gate inspection signal, and the image side driving wiring is supplied with the image side driving signal or the source inspection signal. Image display panel member.

The second invention of the present invention (corresponding to claim 2)
Is provided on the scanning side bypass wiring and has one end connected to the gate wiring and the other end connected to the first connection terminal and the second connection terminal.
A plurality of first switching elements selectively connected to any one of the connection terminals, and one end connected to the source wiring and the other end provided on the image side bypass wiring and a third connection A plurality of second switching elements selectively connected to either the terminal or the fourth connection terminal,
The first connection terminal is connected to the scan side drive wiring,
The third connection terminal is the image display panel member according to the first aspect of the present invention connected to the image side drive wiring.

The third invention (corresponding to claim 3)
Is the number of the gate wirings is 2 m (m: an integer of 1 or more) corresponding to the odd-numbered ones and the even-numbered ones, and the plurality of source wirings are for the R pixel electrodes, There are a total of 3n (n: an integer of 1 or more) of three for the G pixel electrode and the B pixel electrode, and the scanning side drive signal wiring is commonly connected to the odd-numbered gate wiring. And a second sub-signal line commonly connected to the even-numbered gate wirings, and the image-side drive signal wiring is common to the source wirings of each R. Connected to each other, a fourth sub-signal line commonly connected to the source wiring of each G, and a fifth sub-signal line commonly connected to the source wiring of each B. An image display panel member according to the second aspect of the present invention having a sub signal line.

A fourth invention (corresponding to claim 4)
Is the image display panel member according to the third aspect of the present invention, wherein the first switching element and the second switching element are controlled by one common control line.

A fifth aspect of the present invention (corresponding to claim 5)
Is the image display panel member according to the third aspect of the present invention, wherein the first switching element and the second switching element are respectively controlled by independent control lines.

A sixth aspect of the present invention (corresponding to claim 6)
Is the number of the gate wirings is 2 m (m: an integer of 1 or more) corresponding to the odd-numbered ones and the even-numbered ones, and the plurality of source wirings are for the R pixel electrodes, There are a total of 3n (n: an integer of 1 or more) of three for the G pixel electrode and the B pixel electrode, and the scanning side drive signal wiring is commonly connected to the odd-numbered gate wiring. The first sub-signal line and the second sub-signal line commonly connected to the even-numbered gate wirings, and the image-side drive signal wiring includes the source wiring of each R. Each G
And the sixth sub-signal line commonly connected to at least any two types of the source wirings of each B and each of the source wirings of each B, and connected to the source wiring of each R. The second switching element is controlled by a common first control line, and the second switching element connected to the source wiring of each G is controlled by a common second control line and each B is controlled. The second switching element connected to the source wiring is the image display panel member according to the second aspect of the present invention controlled by a common third control line.

A seventh aspect of the present invention (corresponding to claim 7)
Is the number of the gate wirings is 2 m (m: an integer of 1 or more) corresponding to the odd-numbered ones and the even-numbered ones, and the plurality of source wirings are for the R pixel electrodes, There are a total of 3n (n: an integer of 1 or more) sets of three for the G pixel electrode and the B pixel electrode, and the image side drive signal wiring is for each R source wiring and each G The source wiring has two sub-signal lines that are commonly connected to at least any two kinds of wirings of the B source wirings, and each source wiring has first, second, and third wirings. It branches to a third branch source wiring, and for each set of R, G, and B, the first branch source wiring on the R side, the G
Side second branch source wiring and the B side third branch source wiring are respectively connected to one of the two sub-signal lines via the second switching element, and the R side second branch source wiring is connected. And the third branch source wiring, the first and third branch source wirings on the G side, and the first and second branch source wirings on the B side each include the two wires via the second switching element. Connected to the other of the sub signal lines of
The second switching element connected to the first branch source wiring on the G, B side is controlled by a common first control line, and is connected to the second source wiring on the R, G, B side. The second switching element connected is a common second
Controlled by the control line of each of the R, G, B sides of the third
The second switching element connected to the source wiring of is the image display panel member of the second aspect of the present invention controlled by a common third control line.

The eighth invention of the present invention (corresponding to claim 8)
A plurality of first output terminals provided on the gate-side bypass wiring and connected to the gate wirings, and a first input terminal connected to the scanning-side drive signal wiring;
The gate-side bypass includes a plurality of second output terminals provided on the source-side bypass wiring and connected to each of the source wirings, and a second input terminal connected to the image-side drive signal wiring. The wiring has a cut portion between the first output terminal and a connection point of the scan side drive signal wiring and the first input terminal, and the source side bypass wiring is connected to the second output terminal. The image display panel member according to the first aspect of the present invention has a cut portion between the image side drive signal wiring and the connection point of the second input terminal.

A ninth aspect of the present invention (corresponding to claim 9)
Is the image display panel member according to the eighth aspect of the present invention, wherein the cut portion is a thin metal film or a thin metal wire.

A tenth aspect of the present invention (corresponding to claim 10) includes a step of interrupting the conduction of the gate side bypass wiring and the source side bypass wiring of the image display panel member of the first aspect of the present invention, respectively. Providing a scan side drive circuit between the gate line and the scan side drive line;
And a step of providing an image side driving circuit between the source wiring and the image side driving wiring.

The 11th aspect of the present invention (corresponding to claim 11) is the first aspect of the image display panel member according to the 2nd aspect of the present invention.
Switching the switching element so that the second connection terminal is selected, switching the second switching element so that the fourth connection terminal is selected, and the first connection terminal A method of manufacturing an image display panel, comprising: a step of providing a scanning side drive circuit between the gate wiring and the step of providing an image side drive circuit between the third connection terminal and the source wiring.

A twelfth aspect of the invention (corresponding to claim 12) is that the gate-side bypass wiring and the source-side bypass wiring of the image display panel member of the third invention are
Disconnecting by applying a voltage that is equal to or higher than the withstand voltage and is lower than the withstand voltage of any of the gate line, the source line, the scanning side drive signal line, and the image side drive signal line; A method of manufacturing an image display panel, comprising: a step of providing a scanning side drive circuit between a wiring and the scanning side drive wiring; and a step of providing an image side drive circuit between the source wiring and the image side drive wiring. Is.

A thirteenth aspect of the present invention (corresponding to claim 13) is a scan connected to the image display panel member according to the first aspect of the present invention, the gate wiring of the image panel member and the scanning side drive wiring. A side driving circuit and an image side driving circuit connected to the source wiring and the image side driving wiring of the image panel member, and the conduction of the scanning side bypass wiring and the image side bypass wiring of the image panel member , The image display panels are cut off respectively.

According to a fourteenth aspect of the present invention (corresponding to claim 14), the image display panel according to the thirteenth aspect of the present invention and a scanning side drive signal or a gate inspection signal are supplied to the scanning side drive circuit. The image display device includes an original signal supply unit that supplies an image side drive signal or a source inspection signal to an image side drive circuit.

[0023]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) FIG. 1 is a block diagram of an image display device according to Embodiment 1 of the present invention. In the figure, the same or corresponding parts as those in FIG. 7 are designated by the same reference numerals, and detailed description thereof will be omitted. 18 'is an external output circuit, 2
0 is a control wiring, 21a and 21b are scanning side drive signal wirings,
22a, 22b and 22c are image side drive signal wirings, and 23a
Is a scanning side switching element, 23b is an image side switching element, 24a is a scanning side output terminal, 24b is an image side output terminal, 25a is a scanning side input terminal, and 25b is an image side input terminal.

As shown in the figure, all the gate wirings 12 in the liquid crystal panel have scanning side switching elements 23a, and all the source wirings 13 have image side switching elements 23a.
b is added, and the connection of the scanning side switching element 23a and the image side switching element 23b is controlled by one control wiring 20.

Further, scanning side drive signal wirings 21a, 21b
Are connected to the even-numbered and odd-numbered gate wirings 13, respectively, and are further connected to the scanning-side output terminal 24a. In addition, the image side drive signal wirings 22a, 22b, 2
2c denotes all (3n + 1) th source wirings 13, all (3n + 2) th source wirings, and (3n +).
3) All the source wirings 13 are connected. However, here, all the (3n + 1) th source wirings 13 are R
All the (3n + 2) th source wirings 13 are connected to the (red) pixel electrode, and are connected to the G (green) pixel electrode.
All +3) th source wirings 13 are connected to the B (blue) pixel electrodes.

Further, in the scanning side switching element 23a, the first connection terminal 27a is connected to the scanning side drive signal wiring 21a or 21b through the connection wiring 28a, and in addition to the scanning side output terminal 24a, and the second side. Connection terminal 26
a is connected to the scanning side input terminal 25a.

In the image side switching element 23b, the third connection terminal 27b is connected to the image side drive signal wirings 22a, 22b, 22c and the image side input terminal 24a via the connection wiring 28b, and the fourth connection terminal 27b is connected to the fourth side. Connection terminal 2
6b is connected to the image side output terminal 25b.

Further, the external output circuit 18 'outputs a gate drive signal to a gate wiring drive circuit not shown in FIG. 1 via the scanning side drive signal wirings 21a and 21b, and the image side drive signal wirings 22a and 22b. , 22c to output a source drive signal to a source wiring drive circuit not shown in FIG. Upon receiving the gate drive signal, the gate line drive circuit outputs a scanning signal to the gate line 12 based on the gate drive signal,
Upon receiving the source drive signal, the source line drive circuit outputs an image signal to the source line 13 based on the received source drive signal. Further, the external output circuit 18 'includes a scanning side drive signal wiring 21a,
The gate inspection signal is output to the gate wiring 12 via 21b, and the source inspection signal is output to the source wiring 13 via the image side drive signal wirings 22a, 22b, 22c.

The operation of the image display device according to the present embodiment having such a configuration will be described below.

First, when the gate wiring driving circuit and the source wiring driving circuit are not mounted on the liquid crystal panel, a control signal from the control wiring 20 causes the first connecting terminal 27a and the gate to be connected to the gate in the scanning side switching element 23a. Image side switching element 2 connected to wiring 12
3b, the third connection terminal 27b and the source wiring 13
And connect.

As a result, the external output circuit 18 'and the gate wiring 12 are directly connected to each other via the scanning side drive signal wirings 21a and 21b, the auxiliary wiring 28a and the scanning side switching element 23a. Further, the external output circuit 18 ′ and the source wiring 13 are connected to the image side drive signal wirings 22a, 22b, 22.
c, auxiliary wiring 28b and image side switching element 23
It is directly connected via b.

In this state, the gate inspection signal is applied from the external output circuit 18 'to the scanning side drive signal wirings 21a and 21b, and the source inspection signal is applied to the image side drive signal wirings 22a and 2b.
2b22c and a signal is applied to the counter electrode not shown in FIG. 1, white, black, red (R)
A green (G) / blue (B) test display can be performed.

Next, when the gate wiring driving circuit and the source wiring driving circuit are mounted to complete the liquid crystal display panel after completion of the inspection, a control signal from the control wiring 20 causes the scanning side switching element 23a The second connection terminal 26a is connected to the gate wiring 12, and the fourth connection terminal 26b is connected to the image side switching element 23b.
And the source wiring 13 are connected.

Further, the input terminal of the gate wiring drive circuit is the scanning side output terminal 24a, and the output terminal is the scanning side input terminal 25.
Connect to a. Further, the input terminal of the source wiring drive circuit is the image side output terminal 24b, and the output terminal is the image side input terminal 2
Connect to 5b.

As a result, the external output circuit 18 'and the gate wiring 12 are connected via the gate wiring driving circuit. Further, the external output circuit 18 'and the source wiring 13 are
It is connected through a source wiring drive circuit.

In this state, the scanning side driving signal is applied to the scanning side driving signal wirings 21a and 21b from the external output circuit 18 ', and the image side driving signal is fed to the image side driving signal wirings 22a and 2b.
If a signal is applied to 2b22c and a signal is applied to the counter electrode not shown in FIG. 1, normal image display can be performed.

As described above, according to this embodiment, the inspection signal obtained by directly connecting from the external output circuit 18 '
The liquid crystal panel display for testing and the normal liquid crystal panel display using the gate wiring driving circuit and the source wiring driving circuit can be separately provided. Therefore, when a line defect occurs in the liquid crystal panel, the line defect is detected. It is possible to easily determine whether the cause is caused by the above, or whether the cause is caused by a defect on the side of the gate wiring drive circuit or the source wiring drive circuit, that is, the factor separation can be easily performed.

Further, if the auxiliary wirings 28a and 28b and the switching elements 23a and 32b are provided below the positions where the gate wiring driving circuit and the source wiring driving circuit are mounted, the increase in size of the liquid crystal panel can be minimized. it can.

The switching elements 23a and 32b may be switched in advance before mounting the gate wiring drive circuit and the source wiring drive circuit.

Further, the gate wiring 12 and the source wiring 1
Other than the above-described example, there are other electrical connection methods between 3 and the image-side drive signal wiring. For example, as shown in FIG. 2, in order to control the image side switching element 23b, three control wirings 20a, 20b and 20c are prepared,
The control wiring 20a is commonly connected to the R source wiring 13, the control wiring 20b is commonly connected to the G source wiring 13, and the control wiring 20c is commonly connected to the B source wiring 13. Thereby, the image side drive wirings connected to the source wiring 13 via the switching element 23b can be two image side drive wirings 29a and 29b. Further, as shown in FIG. 3, only one of the image side drive wirings 29c may be connected in common with each image side switching element 23b.

The control wiring of the scanning side switching element 23a and the control wiring of the image side switching element 23b may be independent. In this case, as shown in FIG.
From the external output circuit 18 ', the scanning side switching element 2
3a of control wiring 20a and image side switching element 23
The control wiring 20b of b is provided.

Further, as shown in FIG. 5, each source wiring is branched into three, and an image side switching element 23b is provided in each of the branched source wirings, and each of them is sequentially switched from the left side to the image side switching element 23b ( B), (b),
(C) Further, the image side switching element 23b
(A) is connected by the common control wiring 20a, the image side switching element 23b (b) is connected by the common control wiring 20b, and the image side switching element 23b (c) is connected by the common control wiring 20c.

Of all the source wirings, (3n + 1)
The image side switching element 23b (a) connected to the th source wiring 13a and the (3n + 2) th source wiring 1
Image side switching element 23b (b) connected to 3b
And the image side switching element 23b (c) connected to the (3n + 3) th source wiring 13c.
Connected at 2a ', and (3n + 1) of all source wiring
The image-side switching elements 23b (b) and (c) connected to the th source wiring 13a, and the image-side switching element 2 connected to the (3n + 2) th source wiring 13b.
3b (a) and (c), and the image side switching element 23b connected to the (3n + 3) th source wiring 13c.
The configuration may be such that (a) and (b) are connected by the image signal wiring 22b '. Particularly, in the case of this configuration, the number of image signal wirings connected to the source wirings can be reduced from three to two, and a liquid crystal panel with a narrower wiring can be realized.

When one of the gate wiring driving circuit and the source wiring driving circuit can be formed in the same process as the liquid crystal panel like a low temperature polysilicon liquid crystal panel and it is not necessary to mount it later as a semiconductor IC, the driving thereof is performed. The circuit 16 or 17 can be used to display a liquid crystal panel. In this case, in the liquid crystal panel that does not use the semiconductor IC as the gate wiring driving circuit and the source wiring driving circuit, the corresponding gate wiring 12 or source wiring 1
The switching element, the auxiliary wiring and the input / output terminal on the third side may be omitted.

(Second Embodiment) FIG. 6 is a block diagram of an image display device according to the first embodiment of the present invention. In the figure, the same or corresponding parts as those in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted. Further, 30a is a scanning side bypass member, and 30b is an image side bypass member.

As shown in the figure, all the gate wirings 12 in the liquid crystal panel are connected to the scanning side input terminal 25a, and the scanning side input terminal 25a is connected to the scanning side bypass member 30a.
It is connected to the scanning side output terminal 24a and the scanning side drive signal wirings 21a and 21b via.

All source wirings 1 in the liquid crystal panel
3 is connected to the image side input terminal 25b, and the image side input terminal 25b is further connected to the image side output terminal 24b and the image side drive signal wiring 22a via the image side bypass member 30b.
It is connected to 22b and 22c.

Further, the external output circuit 18 'outputs a gate drive signal to a gate wiring drive circuit (not shown in FIG. 1) via the scanning side drive signal wirings 21a and 21b, and the image side drive signal wirings 22a and 22b. , 22c to output a source drive signal to a source wiring drive circuit not shown in FIG. Upon receiving the gate drive signal, the gate line drive circuit outputs a scanning signal to the gate line 12 based on the gate drive signal,
Upon receiving the source drive signal, the source line drive circuit outputs an image signal to the source line 13 based on the received source drive signal. Further, the external output circuit 18 'includes a scanning side drive signal wiring 21a,
The gate inspection signal is output to the gate wiring 12 via 21b, and the source inspection signal is output to the source wiring 13 via the image side drive signal wirings 22a, 22b, 22c.

The operation of the image display device according to the present embodiment having such a configuration will be described below.

First, when the gate wiring driving circuit and the source wiring driving circuit are not mounted on the liquid crystal panel, the external output circuit 18 'and the gate wiring 12 are connected to the scanning side driving signal wirings 21a and 21b and the scanning side bypass. It is connected via the member 30a. In addition, the external output circuit 1
8 ′ and the source wiring 13 are the image side drive signal wiring 22
It is directly connected via a, 22b, 22c and the image side bypass member 30b.

In this state, a gate inspection signal is applied to the scanning side drive signal wirings 21a and 21b from the external output circuit 18 ', and white / black / red (R) is applied to the liquid crystal panel as in the first embodiment.・ Test display of green (G) and blue (B) can be performed.

After completion of the inspection, when the liquid crystal display panel is completed by mounting the gate wiring driving circuit and the source wiring driving circuit, the scanning side bypass member 30a is connected to the scanning side input terminal 25a and the scanning side. The image side bypass member 30b is cut off between the output terminal 24a and the connection point of the scanning side signal drive wirings 21a and 21b, and the image side input terminal 2 is connected.
5b and the connection point of the image side output terminal 24b and the image side signal drive wirings 22a, 22b, 22c,
The scanning side output terminal 24a and the scanning side signal drive wirings 21a, 2
1b and conduction with the scanning side input terminal 25a, the image side output terminal 24b and the image side signal drive wirings 22a, 22b, 22.
The electrical connection with c and the image side input terminal 25b is cut off.

In this state, the input terminal of the gate wiring driving circuit is connected to the scanning side output terminal 24a, the output terminal is connected to the scanning side input terminal 25a, and the input terminal of the source wiring driving circuit is output to the image side output terminal 24b. The terminal is the image side input terminal 25
Connect to b.

As a result, the external output circuit 18 'and the gate wiring 12 are connected via the gate wiring driving circuit.
The external output circuit 18 'and the source line 13 are connected via a source line drive circuit.

As a result, after the test display is completed, the gate wiring driving circuit and the source wiring driving circuit can be mounted and the normal operation can be performed. At this time, if a display problem occurs in the liquid crystal panel, it can be determined that the mounted gate wiring drive circuit and source wiring drive circuit have the cause.

As described above, according to the present embodiment, the structure of the switching element according to the first embodiment is unnecessary, and the size of the liquid crystal panel can be further reduced.

The scanning side bypass member 30a and the image side bypass member 30b can be cut by a method of irradiating a laser to burn off the wiring or a mechanical method such as a cutter. Therefore, the size of the liquid crystal panel is rather increased.

Therefore, the structure of the cut portion 31 of the scanning side bypass member 30a and the image side bypass member 30b is configured as a thin film portion having an extremely thin film thickness so that the heat generated when the gate wiring driving circuit and the source wiring driving circuit are mounted is mounted. And with pressure,
The thin film portion with a small film thickness is cut.

Further, as the cut portion 31, an extremely thin ultrafine wiring having a low withstand voltage is provided instead of the thin film portion, and the scanning side signal drive wiring is provided before the gate wiring drive circuit and the source wiring drive circuit are mounted. 21a, 21b, image side signal drive wirings 22a, 22b, 22c and gate wiring 12
A high voltage of 10 V or more is applied between the source wiring 13 and the source wiring 13 to heat the ultrafine wiring to cut it. At this time, the scanning side input terminal 25a and the image side input terminal 25b are grounded. According to this, it is possible to prevent line defects, disconnection, etc. of the gate wiring 12 and the source wiring 13 due to application of a high potential.

In the above embodiment, the glass substrate 11 corresponds to the substrate of the present invention. Further, the scanning side switching element 23a corresponds to the first switching element of the present invention, and the image side switching elements 23b and 23.
b (b), (b) and (c) correspond to the second switching element of the present invention. Further, the scanning side switching element 23a
The connection wiring 28a and the connection wiring 28a correspond to the scan side bypass wiring of the present invention. The source signal line 13a is the source wiring on the R side of the present invention, and the source signal line 13b is the G line of the present invention.
Side source wiring, and the source signal line 13c corresponds to the B side source wiring of the present invention.

Further, the image side switching element 23b
Source signal line 13a and source signal line 1 connected to (a)
3b and the branch line of the source signal line 13c correspond to the first branch source wiring of the present invention, and the image side switching element 23.
The branch lines of the source signal line 13a, the source signal line 13b, and the source signal line 13c connected to b (b) are the second branch of the present invention.
Corresponding to the branch source wiring of the image side switching element 2
The branch lines of the source signal line 13a, the source signal line 13b, and the source signal line 13c connected to 3b (c) correspond to the third branch source wiring of the present invention.

The image side switching element 23b and the connection wiring 28b correspond to the image side bypass wiring of the present invention. The scanning side drive signal line 21a corresponds to the first sub signal line of the present invention, and the scanning side drive signal line 21b corresponds to the second sub signal line of the present invention. The image-side drive signal line 22a corresponds to the third sub-signal line of the present invention, the image-side drive signal line 22b corresponds to the fourth sub-signal line of the present invention, and the image-side drive signal line 22c is the main. It corresponds to the fifth sub-signal line of the invention.

The image side drive signal lines 29a, 29b,
29c corresponds to the sixth sub-signal line of the present invention, the image signal wiring 22a 'is one of the two sub-signal lines of the present invention, and the image signal wiring 22b' is the two sub-signal lines of the present invention. The control wirings 20a, 20b, 20c correspond to the first control line, the second control line, and the third control line of the present invention, respectively. The external output circuit 18 'corresponds to the original signal supplying means of the present invention.

Further, in each of the above-mentioned embodiments, the image display panel has been described as a liquid crystal panel.
The image display panel member of the present invention may be a panel member having other display means such as a plasma display panel or an EL display panel.

Further, the present invention may be an image display panel member in which the gate wiring driving circuit and the source wiring driving circuit before executing the display test are omitted.

The present invention may also be an image display device equipped with the image display panel of the present invention.

[0068]

As is apparent from the above description, according to the present invention, an image panel can be test-displayed without using an external means for outputting an inspection signal, and an increase in panel size can be minimized. be able to.

[Brief description of drawings]

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

FIG. 2 is a diagram showing another configuration example of the liquid crystal display device according to the first embodiment of the present invention.

FIG. 3 is a diagram showing another configuration example of the liquid crystal display device according to the first embodiment of the present invention.

FIG. 4 is a diagram showing another configuration example of the liquid crystal display device according to the first embodiment of the present invention.

FIG. 5 is a diagram showing another configuration example of the liquid crystal display device according to the first embodiment of the present invention.

FIG. 6 is a configuration diagram of a liquid crystal display device according to a second embodiment of the present invention.

FIG. 7 is a diagram showing an example of a conventional liquid crystal panel.

[Explanation of symbols]

11 glass substrate 12 gate wiring 13 Source wiring 14 pixel electrodes 15 Switching element 16 Gate wiring drive circuit 17 Source drive drive circuit 18 External circuit 18 'external output circuit 19 wiring 20, 20a, 20b, 20c Control wiring 21a, 21b Scanning side drive wiring 22a, 22b, 22c Image side drive wiring 23a Scanning side switching element 23b Image side switching element 24a Scan side output terminal 24b Image side output terminal 25a Scan side input terminal 25b Image side input terminal 26a Second connection terminal 26b Fourth connection terminal 27a First connection terminal 27b Third connection terminal 28a, 28b connection wiring

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) G09G 3/36 G09G 3/36 F term (reference) 2H092 GA40 JA24 JB22 JB31 MA56 NA30 2H093 NA16 NC09 NC18 NC34 NC52 ND53 ND56 NE03 NE07 5C006 AA16 AC11 AF42 AF43 AF53 AF59 AF64 AF65 AF78 BB12 BB16 BC20 BC22 BC23 BF24 BF34 BF42 EB01 EB04 EB05 FA20 FA42 GA02 5C094 AA15 AA53 BA03 BA43 CA19 A435 CC43 DA19 DB01 DB05 EA04 EA05 A17 A12 A05 A17 A12 A5 A17 A12

Claims (14)

[Claims] 1. A substrate, a plurality of gate wirings provided on the substrate, a plurality of source wirings provided on the substrate and intersecting the plurality of gate wirings in a matrix, the gate wirings, and A plurality of pixel driving electrodes connected to the source wiring, a scanning side driving signal wiring for supplying a scanning side driving signal to a scanning line driving circuit which outputs a scanning signal to the gate wiring, and the source wiring. In an image display panel member having an image side drive signal wiring for supplying an image side drive signal to an image line drive circuit for outputting an image signal, a scanning side bypass connecting the gate wiring and the scanning side drive signal wiring At least one of a wiring and an image-side bypass wiring that connects the source wiring and the image-side drive signal wiring is provided, and the scanning-side drive wiring includes a scanning line. Drive signals or gate inspection signal is supplied, wherein the image-side drive wiring, the image display panel member image side drive signal or a source inspection signal is supplied. 2. One end of the scan side bypass wiring is connected to the gate wiring, and the other end is selectively connected to either the first connection terminal or the second connection terminal. A plurality of first switching elements and one end provided on the image side bypass wiring, one end of which is connected to the source wiring, and the other end of which is selectively connected to a third connection terminal or a fourth connection terminal. A plurality of second switching elements connected to each other, wherein the first connection terminal is connected to the scan side drive wiring,
The image display panel member according to claim 1, wherein the third connection terminal is connected to the image side drive wiring. 3. The plurality of gate wirings are 2 m (m: 1) corresponding to odd-numbered ones and even-numbered ones, respectively.
The above-mentioned integers), and the plurality of source wirings are 3 for R pixel electrodes, G pixel electrodes, and B pixel electrodes.
A set of 3n (n: an integer of 1 or more) lines in total, wherein the scanning-side drive signal wirings are the first sub-signal lines commonly connected to the odd-numbered gate wirings, and the even-numbered wirings. A second sub-signal line commonly connected to the gate wiring of, and the image-side drive signal wiring, and a third sub-signal line commonly connected to the source wiring of each R, A fourth sub-signal line commonly connected to the source wiring of each G and each B
5. The image display panel member according to claim 2, further comprising a fifth sub-signal line commonly connected to the source wiring. 4. The image display panel member according to claim 3, wherein the first switching element and the second switching element are controlled by a single common control line. 5. The image display panel member according to claim 3, wherein the first switching element and the second switching element are controlled by control lines independent of each other. 6. The plurality of gate wirings are 2 m (m: 1) corresponding to odd-numbered ones and even-numbered ones, respectively.
The plurality of source wirings are for R pixel electrode, G pixel electrode, and B pixel electrode, and a total of 3n (n: 1).
The scanning side drive signal wirings are commonly connected to the even-numbered gate wirings and the first sub-signal wirings commonly connected to the odd-numbered gate wirings. A second sub-signal line, wherein the image-side drive signal wiring includes the source wiring of each R,
A sixth sub-signal line is connected in common to at least any two kinds of wirings of the source wiring of each G and the source wiring of each B, and is connected to the source wiring of each R. The second switching element is controlled by a common first control line, and the second switching element connected to the source wiring of each G is controlled by a common second control line, The image display panel member according to claim 2, wherein the second switching element connected to the source wiring of each B is controlled by a common third control line. 7. The plurality of gate wirings are 2 m (m: 1) corresponding to odd-numbered ones and even-numbered ones, respectively.
The plurality of source wirings are for R pixel electrode, G pixel electrode, and B pixel electrode, and a total of 3n (n: 1).
The image side drive signal wiring is the source wiring of each R,
The source wiring of each G and the source wiring of each B have two sub-signal lines commonly connected to at least any two kinds of wirings, and each source wiring has It branches into a second and a third branch source wiring, and for each set of R, G, and B, a first branch source wiring on the R side, a second branch source wiring on the G side, The third branch source wiring on the B side is connected to one of the two sub-signal lines via the second switching element, respectively, and the second and third branch source wirings on the R side are provided. The first and third branch source wirings on the G side and the first and second branch source wirings on the B side are respectively connected to the other of the two sub-signal lines via the second switching element. , The R connected to the first branch source wiring on the R, G, B side 2 switching elements are controlled by a common first control line, and the second switching elements connected to the R, G, B side second source lines are common second control lines. The image display panel according to claim 2, wherein the second switching element controlled by the third control line and connected to the third source wiring on each of the R, G, and B sides is controlled by a common third control line. Element. 8. A plurality of first output terminals provided on the gate-side bypass wiring and connected to each of the gate wirings, and a first input terminal connected to the scanning-side drive signal wiring, A plurality of second output terminals connected to the source wirings and a second input terminal connected to the image side drive signal wirings, the gate side bypass wirings being provided on the source side bypass wirings; Is the first output terminal,
A disconnection portion is formed between the scan side drive signal wiring and the connection point of the first input terminal, and the source side bypass wiring is connected to the second output terminal;
The image display panel member according to claim 1, further comprising a cut portion between the image side drive signal wiring and the connection point of the second input terminal. 9. The image display panel member according to claim 8, wherein the cut portion is a thin metal film or a thin metal wire. 10. A step of interrupting electrical connection between the gate side bypass wiring and the source side bypass wiring of the image display panel member according to claim 1, and scanning between the gate wiring and the scanning side drive wiring. A method of manufacturing an image display panel, comprising: a step of providing a side drive circuit; and a step of providing an image side drive circuit between the source wiring and the image side drive wiring. 11. A step of switching the first switching element of the image display panel member according to claim 2 so that a second connection terminal is selected, and a step of switching the second switching element to a fourth switching element. A step of switching so that the connection terminal is selected; a step of providing a scanning side drive circuit between the first connection terminal and the gate wiring; and an image between the third connection terminal and the source wiring. And a step of providing a side drive circuit. 12. The gate wiring and the source-side bypass wiring of the image display panel member according to claim 3, the gate wiring having a withstand voltage or more,
A step of disconnecting by applying a voltage lower than a withstand voltage of any of the source wiring, the scanning side driving signal wiring and the image side driving signal wiring; and scanning between the gate wiring and the scanning side driving wiring. A method of manufacturing an image display panel, comprising: a step of providing a side drive circuit; and a step of providing an image side drive circuit between the source wiring and the image side drive wiring. 13. The image display panel member according to claim 1, a scanning side drive circuit connected to the gate wiring and the scanning side drive wiring of the image panel member, the source wiring of the image panel member, and An image display panel, comprising: an image-side drive circuit connected to the image-side drive wiring; and electrical connection between the scanning-side bypass wiring and the image-side bypass wiring of the image panel member is cut off. 14. The image display panel according to claim 13, wherein a scanning side drive signal or a gate inspection signal is supplied to the scanning side drive circuit, and an image side drive signal or a source inspection signal is supplied to the image side drive circuit. An image display device provided with an original signal supply means for supplying.