KR19990013695U - Automatic production apparatus for display monitor using SUS - Google Patents

Abstract

The present invention relates to an automatic production apparatus using USB, a PC having a factory mode and a USB program installed, a display monitor for receiving and storing a factory mode transmitted from the PC through USB communication, and a display on the display monitor. The new model is developed by displaying the full white pattern, analyzing and transmitting the color analyzer to the PC, and removing the jig for I ² C communication in the process of storing and adjusting the factory mode on the display monitor. It is possible to easily modify the time program factory mode, to accurately measure the initial data measurement, and to reduce communication defects during production.

Description

Automatic production apparatus for display monitor using SUS

The present invention relates to an automatic production apparatus using a universal serial bus (hereinafter abbreviated as USB), and in particular, a USB program is installed on a PC that controls production in an automatic production process of a display monitor, and then displayed. The present invention relates to an automatic production apparatus using USB for controlling the production of a monitor.

In general, a display monitor is a process of adjusting an accurate screen state so that a user conveniently uses the display monitor in a factory mode adjustment process. In other words, the display monitor being manufactured using an external adjustment jig and the I ² C bus are used to transmit timing data such as horizontal / vertical synchronization frequency, synchronization frequency polarity, monitor resolution, and display monitor information data. It is a process.

The factory mode stored by the factory mode adjustment process causes the screen state by the factory mode data to be displayed on the display monitor if there is no user mode data adjusted by the user after the display monitor is powered on.

An example of such a factory adjustment process will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the display monitor 200 which is in factory mode adjustment through the parallel control (②) for I ² C communication (①) and PWM up / down (UP / DOWN). Is transmitted to and stored in a storage means (not shown). When the screen adjustment data is stored in the storage means of the display monitor 200, the display monitor 200 displays a full white pattern.

The full white pattern displayed on the display monitor 200 is analyzed by the color analyzer 300 again through parallel communication (②) for PWM up / down and the result is RS-232C communication (③). It is transmitted to the PC 400 through. The PC 400, which has received the analysis result of the full white pattern displayed on the display monitor 200 by the color analyzer 300, analyzes the result and performs the microcomputer through RS-232C communication (④). The jig 100 is transmitted.

That is, if the full white pattern displayed on the display monitor 200 is analyzed by the color analyzer 200 as not being normally displayed, the PC 400 transmits the corrected data to the microcomputer jig 100 through the RS-232C. Transmit through communication (④). The correction data transmitted to the microcomputer jig 100 is transmitted to the display monitor 200 through I ² 2 communication (①).

The display monitor 200 receiving the corrected screen adjustment data through I ² C communication (①) stores the data in the storage means to display the full white pattern. The full white pattern displayed on the display monitor 200 is analyzed by the color analyzer 300 again, and the result is transmitted to the PC 400 through RS-232C communication (③). Through this repeated process, the screen displayed on the screen of the display monitor 200 is adjusted to store the factory mode of the display monitor 200 in the storage means.

Thus, because by using a factory mode adjustment I ² C communication of the display monitor is needed the microcomputer jig Further, a problem that the defect of the display monitor occurrence is made if a communication failure due to the I ² C communication occurs is caused .

Therefore, an object of the present invention is to provide an automatic production apparatus for transmitting factory mode data directly through USB communication to a display monitor and storing the data by using a PC with a USB program installed to solve the above problems.

The present invention for achieving the above object is a PC with a factory mode and a USB program is installed, a display monitor for receiving and storing the factory mode transmitted from the PC via USB communication, and a full white displayed on the display monitor It is characterized by consisting of a color analyzer to display a pattern (Full white pattern) to analyze and transmit to the PC.

1 is a block showing an embodiment of an automatic production apparatus of a conventional display monitor

Diagram,

2 shows an embodiment of an automatic production apparatus for a display monitor according to the present invention

It is a block diagram.

Looking at the present invention using the accompanying drawings as follows.

2 is a block diagram showing an embodiment of an automatic production apparatus for a display monitor according to the present invention. As shown, a PC 10 having a factory mode and a USB program installed therein, a display monitor 20 for receiving and storing a factory mode transmitted from the PC 10 by using USB communication ① ', And a color analyzer 30 which displays a full white pattern displayed on the display monitor 20, analyzes the data, and transmits the analyzed data to the PC 10.

Looking at this configuration in more detail as follows.

First, a USB program is installed in the PC 10. When the USB program is installed in the PC 10, the PC 10 and the display monitor 20 are connected to enable USB communication (① ′). When USB communication (① ') is possible between the PC 10 and the display monitor 20, the PC 10 is factory mode data, and the horizontal / vertical synchronization frequency, the synchronization frequency polarity, the resolution of the monitor, and the display monitor are the timing data. Information data and the like are transmitted to storage means (not shown) of the display monitor 20 for storage.

The display monitor 20, which receives the factory mode data transmitted by the control of the USB program from the PC 10 through the USB communication (① ') and stores it in the storage means, displays a full white pattern in the case of a screen adjustment process. Display. The full white pattern displayed on the display monitor 20 is analyzed by the color analyzer 30.

The result of analyzing the full white pattern by the color analyzer 30 is transmitted to the PC 10 again. At this time, the color analyzer 30 and the PC 10 are connected by the RS-232C communication (2 ''), and the result analyzed through the RS-232C communication (2 '') is transmitted to the PC 10.

Upon receiving the analysis result, the PC 10 determines whether the result is SPEC.IN. As a result of the determination, when the full white pattern displayed on the screen of the display monitor 20 becomes SPEC. IN, the screen adjustment is completed. In the same way, factory mode adjustments other than screen adjustments are made in the same way.

On the contrary, if the full white pattern displayed on the screen of the display monitor 20 is SPEC. OUT, the PC 10 corrects the result transmitted before the color analyzer 30 to perform USB communication (① '). PWM up / down is performed through

That is, the display monitor 20 which has received the data corrected by the PC 10 through the USB communication ① 'stores the transmitted correction data in the storage means and displays the full white pattern on the screen accordingly. . The displayed full white pattern is analyzed by the color analyzer 30 again and the result is transmitted to the PC 20 through the RS-232C communication (2 ').

Upon receiving the result analyzed through RS-232C communication ② ', the PC 10 determines whether it is SPEC.IN or SPEC.OUT. As a result of the determination, the screen adjustment is terminated if the specification is SPEC. IN, and the result analyzed by the color analyzer 30 is corrected if the specification is SPEC. OUT, and PWM up / down is performed through the USB communication ① '. Perform (UP / DOWN).

Through this repeated process, the PC 10 may transmit and store the screen adjustment data directly to the display monitor 20 through the USB communication ① ′. In addition, factory mode adjustments other than screen adjustments can be adjusted in the same way.

Therefore, by installing the USB program on the PC 10 and controlling the USB communication (① ') by the program, it is possible to transmit the factory mode data to the display monitor 20 more accurately and without error (Error).

As described above, the present invention eliminates the need for a jig for I ² C communication in the process of storing and adjusting the conventional factory mode on the display monitor, thereby facilitating modification of the program factory mode when developing a new model. In the initial data measurement, accurate measurement is possible and communication defects during production are reduced.

Claims (2)

PC with factory mode and USB program installed, A display monitor for receiving and storing the factory mode transmitted from the PC through USB communication; And a color analyzer configured to display, analyze, and transmit a full white pattern displayed on the display monitor to the PC. The method of claim 1, Communication for transmitting the results analyzed by the color analyzer to the PC using the RS-232C characterized in that the automatic production apparatus of the display monitor using a USB.