JP2003015544A - Aging apparatus and aging method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an aging apparatus and an aging method, in which aging is conducted for a plurality of liquid crystal modules all at once and the aging is flexibly performed, even though the kinds of the liquid crystal modules are varied. SOLUTION: An aging device 10 consists of a signal generator 14, which generates differential signals to display images on liquid crystal modules 16, a plurality of distribution devices 12 which include input sections 26 used for receiving the differential signals and a plurality of output sections 28 that output the differential signals and signal paths which are formed to connect a plurality of the devices 12 via signal lines in serial and parallel, or in combinations of serial and parallel.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an aging device and an aging method capable of aging a plurality of liquid crystal modules at one time and flexibly responding to changes in the types of liquid crystal modules.

[0002]

2. Description of the Related Art A liquid crystal module is subjected to aging as an accelerated test during the manufacturing process. In aging, the liquid crystal module is placed in a temperature condition of about 50 to 85 degrees for a certain period of time, and images with different colors and brightness are displayed one after another.
At that time, an image of the liquid crystal module is displayed during or after aging to detect a defective product.

Generally, in an aging device, a liquid crystal module and a signal generator for sending a display signal to the liquid crystal module have a one-to-one relationship. That is, the display signal generated by one signal generator is sent to one liquid crystal module.

However, when the type of liquid crystal module changes, it is necessary to change the signal generator. As the aging device performs the aging of many liquid crystal modules at one time, the economic burden of changing the signal generating device is large.

Therefore, a method in which one signal generator is used and display signals are transmitted to a plurality of liquid crystal modules via a signal distributor is considered. In this case, even if the type of liquid crystal module is changed, only one signal generator needs to be changed.

However, when the signal transmission path from the signal generator to the liquid crystal module is configured by a parallel interface, it is a common practice to distinguish display signals (data "0" and "1" depending on voltage) in the signal distributor. Buffer chip that distributes various digital signals) is required. When the display signal is distributed, noise is introduced into the display signal by the signal transmission path or the buffer chip, and the display signal is deteriorated. Distributing the display signal in parallel and transmitting the display signal to the plurality of liquid crystal modules in this manner causes deterioration of the display signal.

[0007]

SUMMARY OF THE INVENTION An object of the present invention is to provide an aging device capable of aging a plurality of liquid crystal modules at one time by stable distribution of display signals and flexibly responding to changes in the types of liquid crystal modules. It is to provide an aging method.

[0008]

SUMMARY OF THE INVENTION An aging device of the present invention is provided with a signal generator for generating a display signal for displaying an image on a liquid crystal module and outputting the signal as a differential signal, and the display signal is a differential signal. An input section that is input as a signal,
And a plurality of distribution devices including a plurality of output units for outputting the display signals as differential signals, and the plurality of distribution devices are connected to each other via signal lines in series, in parallel, or in a combination of series and parallel. And a signal transmission path formed as described above.

The distribution device further includes a serial / parallel converter for performing serial / parallel conversion of a display signal input as a differential signal to the input section, and a parallel of the display signal converted by the serial / parallel converter. A plurality of parallel-serial converters that perform serial conversion, and a distribution circuit that distributes the display signals that are serial-parallel converted by the serial-parallel converters to the plurality of parallel-serial converters that output differential signals ,including.

An interface for forming the signal transmission path is an LVDS (Low Voltage Differential S
ignaling) interface. The differential signal transmitted through the signal transmission path includes an LVDS signal.

The number of the output units included in one distribution device is 2 to 6.

The distribution device is arranged and includes a constant temperature bath in which a liquid crystal module is placed.

The gist of the aging method of the present invention is that the signal generator generates a differential signal, and the differential signal connects a plurality of distributors in series, in parallel, or in a combination of series and parallel. The method includes transmitting on the formed signal transmission path, and displaying an image on the liquid crystal module connected to the distributor.

Further, a step of performing serial / parallel conversion of the display signal input as a differential signal to the distribution device, a step of performing parallel / serial conversion of the display signal subjected to serial / parallel conversion, and a step of parallel / serial conversion. Outputting the display signal as a differential signal from the distributor.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION An aging device and an aging method of the present invention will be described with reference to the drawings.

As shown in FIG. 1, the aging device 10 includes a signal generator 14 for generating a display signal and outputting it as a differential signal, and a plurality of distributors 1 for distributing the differential signal.
2 and a signal transmission path formed by connecting a plurality of distribution devices 12 in series, parallel, or a combination of series and parallel.

As shown in FIG. 2, the distributor 12 is provided with one input section 26 and a plurality of output sections 28. The input section 26 of one distribution apparatus 12 and the output section 28 of another distribution apparatus 12 are connected by a differential signal line 13 to form a signal transmission path. The output unit 28 that is not connected to the input unit 26 of the other distribution device 12 and the liquid crystal module 16 are connected by the differential signal line 13. According to the inventor's experiment, it is preferable that the number of output units 28 provided in one distribution device 12 is 2 to 6 in consideration of the wiring between the distribution device 12 and the liquid crystal module 16.

The distribution device 12 also includes a serial / parallel converter 30 for performing serial / parallel conversion of the display signal input as a differential signal to the input unit 26, and a display signal converted by the serial / parallel converter 30. Multiple parallel-serial converters 3 that perform parallel-serial conversion
Including 2. Further, the display signal converted by the serial / parallel converter 30 is converted into a plurality of parallel / serial converters 32.
It includes a distribution circuit 33 for distributing to. The distribution circuit 33 can be formed by a general bus line. As described above, the transmission of the display signal is performed in the parallel format inside the distribution device 12, and is performed outside the distribution device 12 in the serial format based on the differential signal. Further, the display signal is in the distribution device 12 in the form of a general digital signal for distinguishing "0" and "1" data by voltage.

The interface of the signal transmission path is LVD
Includes S (Low Voltage Differential Signaling) interface. The LVDS interface is a type of interface for performing differential signal transmission.
The configuration of the LVDS interface is as shown in FIG.
The driver 29 and the receiver 27 are connected by a pair of differential signal lines 13. The driver 29 is the output unit 28 in FIG. 2, and the receiver 27 is the input unit 26. In the differential signal transmission, a signal transmitting side and a signal receiving side are connected by a pair of differential signal lines, and "0" data or "1" is determined depending on which signal line has a higher or lower potential. This is a signal transmission for determining the data.

The differential signal transmitted through the signal transmission path of the LVDS interface is the LVDS signal. LVD
The S signal is a kind of differential signal, and the pair of differential signal lines 13
It is determined whether the transmitted signal is "0" data or "1" data, depending on which of the two potentials is higher or lower. The LVDS signal is several hundred mV (for example, 350 mV
V), which is a low-voltage signal, and EMI (Electro Magn
etic Interference: Electromagnetic interference) noise is less likely to occur. In addition, high frequency transmission is possible. LVD
Serial signal transmission of the S signal enables high-speed transmission as compared with parallel transmission, and the number of differential signal lines 13 can be reduced. For example, transmission at 1 Gbps is possible.

In addition to being connected to the distribution device 12, the liquid crystal module 16 is also connected to a power source 18 via an inverter 20 to operate the backlight of the liquid crystal module 16.
It is connected to the. The distribution device 12 is also connected to the power supply 18. The power supply 18 includes a switch 22 for controlling the power supply to each distribution device 12 and the liquid crystal module 16.
Are connected. The switch 22 can turn on or off the distribution device 12 and the liquid crystal module 16. Further, the signal generator 14 is provided with an operation box 24 so that the display signal can be changed.

In addition, a constant temperature bath in which the distribution device 12 is installed and the liquid crystal module 16 is placed is provided. The temperature of the constant temperature bath during aging is 50 to 85 degrees. The aging time varies depending on the type of the liquid crystal module 16 to be targeted or the test purpose. For example, in a reliability test,
About 100 hours or more, and about 1 hour for a small panel.

From the above, the aging device 10 of the present invention.
Is a plurality of liquid crystal modules 1 with one signal generator 12.
Aging of 6 can be performed. By using the LVDS signal, it is possible to transmit the same display signal to any liquid crystal module 16 without deterioration of the display signal.

Next, an aging method using the aging device 10 will be described. After connecting the liquid crystal module 16 to the distribution device 12 as shown in FIG. 1, the temperature of the constant temperature bath is raised to 50 to 85 degrees. In this temperature state, the signal generator 14 generates a display signal for displaying an image on the liquid crystal module 16. This display signal uses an LVDS signal which is a kind of differential signal. It is also possible to change the display signal by the operation box 24 to change the image displayed on the liquid crystal module 16.

The generated LVDS signal is transmitted to the liquid crystal module 16 via the differential signal line 13 and the distribution device 12. Since the distribution device 12 is a device that outputs a plurality of signals with one input, the distribution device 12 distributes the display signal to a plurality of pieces on the way. After that, since it is re-converted into the LVDS signal, the noise when distributed can be almost completely removed, and stable display signal transmission becomes possible.

The display signal is transmitted through the differential signal line 13 as an LVDS signal in a serial format. When the LVDS signal is input to the input unit 26 of the distribution device 12, the serial / parallel converter 30 performs serial / parallel conversion. Therefore, the transmission of the display signal in the distribution circuit 33 is performed in parallel. Further, the display signal is parallel-serial converted by the parallel-serial converter 32, and the differential signal line 13 connected to the output unit 28 receives the LV signal.
It is transmitted in serial form as a DS signal.

Liquid crystal module 1 which has received the LVDS signal
6 displays an image according to the signal. The signal generator 14 generates LVDS signals one after another for a defined time. The liquid crystal module 16 receives the LVDS signals one after another and displays an image in a constant temperature bath of 50 to 85 degrees.
Although it depends on the type of the liquid crystal module 16, it is necessary to perform a predetermined number of refreshes per second for each pixel of the liquid crystal forming the liquid crystal module 16. For example, if the liquid crystal module 16 has a resolution of 1024 × 768 pixels, the liquid crystal module 16 receives the LVDS signal about 65 × 10 ^{6 to} 94.5 × 10 ⁶ times per second in order to refresh all the pixels. To do.

After aging for a specified time, an image is displayed on the liquid crystal module 16 at room temperature. Liquid crystal module 1 that does not display a predetermined display or does not display at all
6 is treated as a defective product. The display can be confirmed by human eyes.

Although the embodiments of the aging apparatus and the aging method of the present invention have been described above, the present invention is not limited to the above embodiments. For example, although the signal transmission path is formed by connecting the distribution devices 12 in series in FIG. 1, the signal transmission path may be configured by a combination of series and parallel as shown in FIG.

The number of liquid crystal modules 16 connected to one distribution device 12 is not limited to one or two.
It is also possible to connect the three liquid crystal modules 16 to one distribution device 34 as shown in FIG. 6 by using the distribution device 34 provided with the three output sections 28 as shown in FIG. Further, the number of the output units 28 provided in the distribution device 34 is not limited, and any number can be used.

L as an interface of the signal transmission path
Although the VDS interface is used, it is not limited to the LVDS interface. For example, Panel Link and GV
IF (Giga-bit Video InterFace) may be used.
In this case, the display signal transmitted through the signal transmission path uses a Panel Link signal or a GVIF signal which is a kind of differential signal.

Although the liquid crystal modules 16 are connected to all the distribution devices 12 in FIG. 1, the liquid crystal modules 16 are not necessarily connected to all the distribution devices 12. If there is a distribution device 12 to which the liquid crystal module 16 is not connected,
The power of the distribution device 12 is turned off by the switch 22. Even if the liquid crystal module 16 is connected to the distribution device 12, the power of the distribution device 12 and the liquid crystal module 16 can be turned off by the switch 22.

In addition, the present invention can be carried out in a mode in which various improvements, modifications and variations are added based on the knowledge of those skilled in the art without departing from the spirit of the present invention.

[0034]

According to the present invention, it is possible to transmit differential signals from one signal generator to a plurality of liquid crystal modules for aging, and it is not necessary to prepare a plurality of signal generators. Therefore, even if the type of the liquid crystal module is changed, only one signal generator needs to be changed, and the economical burden is small.

Further, the signal transmission path for transmitting the differential signal can be flexibly configured, and the signal transmission path can be flexibly changed according to the shape of the constant temperature bath in which the liquid crystal module is placed. it can. The differential signal has less deterioration of the signal and can transmit the differential signal to many liquid crystal modules at the same time, so that many liquid crystal modules can be aged at one time.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of an aging device of the present invention.

FIG. 2 is a block diagram showing a configuration of a distribution device.

FIG. 3 is a diagram showing an LVDS interface.

FIG. 4 is a diagram showing a configuration example of a signal transmission path other than that shown in FIG.

FIG. 5 is a block diagram showing another configuration example of the distribution device.

6 is a diagram showing a configuration example of a signal transmission path when the distribution device of FIG. 5 is used.

[Explanation of symbols]

10: Aging device 12, 34: Distributor 13: Differential signal line 14: Signal generator 16: Liquid crystal module 18: Power supply 20: Inverter 22: Switch 24: Operation box 26: Input section 27: Receiver 28: Output section 29: Driver 30: Serial / parallel converter 32: Parallel / serial converter 33, 36: Distribution circuit

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kazuhiko Nakamura             800 Miyake, Yasu-cho, Yasu-gun, Shiga Prefecture             Aites Co., Ltd. F-term (reference) 2G132 AA00 AB03 AE27 AG01 AL00                       AL06 AL21                 2H088 FA11 FA30 MA20                 5C006 BB11 EB01                 5C080 AA10 BB05 DD28 JJ02                 5G435 AA17 BB12 CC09 KK05 KK10

Claims (7)

[Claims] 1. A signal generator for generating a display signal for displaying an image on a liquid crystal module and outputting the display signal as a differential signal, an input section to which the display signal is input as a differential signal, and the display signal. Are output as differential signals, a serial / parallel converter for performing serial / parallel conversion of display signals input as differential signals to the input section, and a display converted by the serial / parallel converter. A plurality of parallel / serial converters for performing parallel / serial conversion of signals, and a display signal serial / parallel converted by the serial / parallel converter is output as a differential signal and distributed to the plurality of parallel / serial converters. A plurality of distribution devices including a distribution circuit and the plurality of distribution devices are connected to each other in series, in parallel, or in a combination of series and parallel via signal lines. Therefore, an aging device including a signal transmission path formed by being connected. 2. An interface for forming the signal transmission path is LVDS (Low Voltage Differential).
Aging device according to claim 2, comprising a Signaling interface. 3. The aging device according to claim 1, wherein the differential signal includes an LVDS signal. 4. The aging device according to claim 1, wherein the number of the output units included in one distribution device is 2 to 6. 5. The aging device according to claim 1, further comprising a constant temperature bath in which the distribution device is arranged and a liquid crystal module is placed. 6. A step of generating a differential signal by a signal generator, the differential signal being on a signal transmission path formed by connecting a plurality of distributors in series, in parallel, or in a combination of series and parallel. An aging method comprising: a step of transmitting and a step of displaying an image on a liquid crystal module connected to the distributor. 7. A step of serial-parallel converting a display signal input as a differential signal to the distribution device,
The aging method according to claim 6, further comprising: a step of performing parallel / serial conversion on the serial / parallel converted display signal; and a step of outputting the parallel / serial converted display signal as a differential signal from the distributor.