KR100275011B1 - Monitor id auto registration system - Google Patents

Abstract

The system for automatically inputting the unique information of the monitor of the present invention, which automatically performs the unique information input process of the monitor which has been performed by the operator's manual operation, monitor transfer means and monitor unique information for transferring the monitor being manufactured to the work position of each process. And generating the monitor peculiar information into the monitor waiting to receive the monitor peculiar information, and when the input of the peculiar monitor peculiar information is completed, driving the monitor transfer means to transfer the monitor to the work position of the next process. It is made with a computer.

Description

Unique information input system of monitor

The present invention relates to a monitor, and more particularly, to an EDID automatic input system of a monitor.

A display using a cathode ray tube (hereinafter, abbreviated as CRT) among the display devices that display the results of signal processing using a computer in an easy-to-understand manner displays the result of the signal processing as an image.

The CRT is constructed by attaching an electron gun to a vacuum tube, and when the image signals R, G and B output from a computer video card (not shown) are amplified at high pressure and applied to the electron gun, an electron beam is emitted into the vacuum tube. The electron beam emitted to the tube is deflected by deflection yoke and advanced by the acceleration force of the anode to reach the fluorescent film of the CRT.

The electron beam moves obliquely from left to right on the fluorescent film. When the right end is reached, the electron beam returns to the left end, which is the first position of the next row, and then moves diagonally again. The period during which the electron beam moves from side to side is referred to as the effective syringe, while the period of returning to the beginning of the next line after completing the scanning of one line is called the return period.

In order to move the electron beam, the sawtooth voltage signal must be transmitted to the deflection yoke so that the deflection yoke can exert its deflection force. The sawtooth voltage signal is a horizontal / vertical synchronization signal (H-SYNC / V-) transmitted from the video card. SYNC).

There are two methods of transmitting the horizontal / vertical sync signal and the video signals R, G, and B output from the video card to the monitor, BNC and D-SUB.

First, the BNC method transmits a video signal and a horizontal / vertical sync signal separately through separate cables, and the D-SUB method transmits a video signal and a sync signal through one cable.

DDC (Display Data) is a function that transmits various information about the monitor to the computer through the D-SUB method so that the computer can display the optimal screen corresponding to the unique information of the monitor on the monitor. Channel).

In this case, the unique information of the monitor transmitted from the monitor to the computer includes the date of manufacture of the monitor, a serial number indicating the model name of the product, a manufacturer's ID, a usable frequency range, and power saving of the monitor. Includes support for Display Power Management Signaling, CRT characteristics, and the appropriate mode of use.

The unique information is required to be stored in advance in a monitor memory or a DDC IC (IC dedicated to the DDC function) based on a standard provided by the Video Eletronics Standards Association (VESA). This storage operation is performed in a unique information input process after assembling the monitor and adjusting basic usage environments such as tilt, brightness, contrast, and horizontal / vertical size of the screen.

Most computer users have little knowledge of how much resolution their monitors support or what resolution is appropriate for their current software. Therefore, even if you have a high-performance monitor, you are not using the monitor properly when using software that requires high resolution screens such as CAD or games.

However, if DDC is supported, the monitor sends its own information to the computer, and the computer receives the information to control the monitor, so users who are not familiar with the monitor's knowledge and operation, regardless of the type of software they are using You can get the best monitor environment.

The process of inputting the unique information of the monitor to the monitor is as follows.

The unique information input process is performed by a computer dedicated to the process. When the assembled and adjusted monitor is loaded on the monitor pallet and transported to the installation site of the computer, the waiting worker scans the barcode attached to the outside of the monitor in the assembly process using a barcode reader.

Scanned barcode information is input to the working computer, and the computer that receives the barcode information generates the final monitor unique information by combining the product information file for each model of the monitor and the serial number provided by the barcode information. do.

The unique information generated in this way is transmitted to the monitor through the D-SUB method. When the operator connects the 15-pin D-SUB connector, which is the terminal of the D-SUB cable connected to the computer at one end, to the monitor, and sends a command by clicking the mouse or keyboard of the computer, the monitor's unique information is transmitted from the computer to the monitor. And stored.

When the monitor unique information transmitted to the monitor is stored smoothly in the DDC IC or the monitor memory, the monitor sends a signal to the computer indicating the completion of the storage. The storage completion signal received from the monitor is displayed on the output device (monitor, LCD, etc.) of the computer, and the user who confirms this drives the monitor carrier and moves the monitor to the work place where the next process is to proceed.

In the conventional unique information input process as described above, since the overall procedure is performed by the manual labor of the operator, sometimes a mistake of the operator may occur, and the operation progress speed is relatively slow. In addition, it is difficult to reduce the production cost of the monitor in consideration of the labor cost of workers.

An object of the present invention is to provide a system for automatically inputting unique information of a monitor so that the process of inputting unique information of the monitor can be automatically performed without a separate operation of an operator.

The system for automatically inputting unique information of the monitor according to the present invention for this purpose generates a monitor transfer means and monitor unique information for transferring a monitor being manufactured to a work position for each process, and sends the monitor unique information to a monitor waiting to receive the monitor unique information. And a computer for inputting the generated monitor unique information and driving the monitor transfer means to transfer the monitor to a work position of a next process when the input of the monitor unique information is completed.

1 is a block diagram showing the circuit configuration of a system for automatically inputting unique information of a monitor according to the present invention;

2 is I ² C Timing diagram of the SDA signal and the SCL signal transmitted between the interface unit and the DDC IC,

3 is a flow chart for explaining the overall procedure of data communication between the computer and the monitor.

* Explanation of symbols on main parts of drawings *

1: Monitor 11: DDC IC

12: RAM (for monitor) 2: Monitor feeder

3: monitor carrier 4: computer

41: CPU 42: video card

43: RAM (for computer) 44: RS-232C interface

45: monitor feeder interface 46 I ² C Interface part

5: computer platform 51: contact sensor

8,9: 15-pin D-SUB connector

Hereinafter, a system for automatically inputting unique information of a monitor according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the circuit configuration of a system for automatically inputting unique information of a monitor according to the present invention.

As shown in FIG. 1, the automatic system for inputting unique information of a monitor is used in every step of manufacturing a monitor, from assembling the monitor 1 to adjusting the basic usage environment and inputting unique information. A monitor feeder (2) for transporting the monitor to the working position of the process, a monitor carriage (3) for supporting each monitor (1) which is carried on the monitor feeder (2), and the unique information of the monitor. It comprises a computer 10 for generating and transmitting to the monitor 1, and a workbench 5 on which the computer is installed.

The computer 4 includes a bar code reader 6 as a peripheral device and a monitor transfer device actuator 7, and on one side of the computer 4, a D-SUB used for transmitting monitor specific information to the monitor 1. A cable (not shown) is connected. The terminal of the cable is provided with a 15-pin D-SUB connector (8).

Inside the computer 4, a central processing unit (hereinafter, referred to as a CPU) performs various operations in connection with a series of tasks for generating and transmitting monitor unique information to the monitor 1, and controlling each component of the computer 4; 41 and horizontal / vertical synchronization required when the monitor 1 receives and displays the image signal while processing and outputting the calculation result of the CPU 41 as the image signals R, G, and B. A video card 42 for outputting a signal H-SYNC / V-SYNC and a RAM 43 for storing a model-specific product information file of the monitor 1 are provided.

The CPU 41 has a ROM (not shown) in which control commands necessary for the entire process of inputting a unique command of the monitor are organically performed are stored. When the video card 42 displays an error occurring during the process of inputting the unique information of the monitor 1 in the form of a text or an image, the video card 42 is a display means separately provided in the computer 4. In case that there is a video signal among the monitor specific information, the video signal is transmitted to the monitor 1.

An RS-232C interface unit 44 is connected between the barcode reader 6 and the CPU 41 to control a communication method, a communication speed, and the like of data and control signals between the barcode reader 6 and the CPU 41. . Similarly, the monitor feeder interface unit 45 is also connected between the monitor feeder actuator 7 and the CPU 41 to create a smooth communication environment between the monitor feeder actuator 7 and the CPU 41.

In addition, between the CPU 41 and the 15-pin D-SUB connector 8 I ² C The interface unit 46 is connected to transfer data between the computer 4 and the monitor 1. I ² C Control to be performed by protocol.

One side of the workbench 5 of the computer 4 is equipped with a contact sensor 51, the monitor carrier (3) on which the monitor (1) is mounted is mounted on the monitor feeder (2) and close to the computer workbench (5). When it is moved to, it detects it.

The monitor 1, which receives the monitor specific information from the computer 4 having the above-described configuration, is mounted on the monitor feeder 2 and moved to the work position of each process while being seated on the monitor carriage 3. .

The monitor 1, which has already been assembled and adjusted, includes a video signal processing unit for amplifying a video signal input from the outside including the CRT and applying it to an electron gun in the CRT, and applying a sawtooth signal to the deflection yoke. And a deflection circuit portion and all components such as a high voltage generator for applying a high voltage signal to the anode.

In the case of a monitor employing DDC, the DDC IC 11 is further provided. The DDC IC 11 reads out the monitor unique information at the initial stage of power-up and transmits the monitor unique information to the computer 4, and also stores the monitor unique information transmitted from the computer 4 to the monitor 1 during the monitor manufacturing process. Dedicated to DDC-related tasks, such as storing in.

A D-SUB cable is also connected to the monitor 1, and a 15-pin D-SUB connector 9 formed in a structure that can be connected to the D-SUB connector 8 of the computer 4 is provided at the terminal of the D-SUB cable. do. The monitor specific information transmitted from the computer 4 to the monitor 1 is transmitted to the DDC IC 11 via the D-SUB cable, and the RAM 12 is relatively free to write and read under the control of the DDC IC 11. Are stored in.

In the circuit diagram of the monitor 1 in the block diagram of FIG. 1, only the DDC IC 11 and the RAM 12 are shown for easy understanding of the present invention, and other components are omitted.

On one side of the external surface of the monitor 1 having such a circuit configuration, a bar code label indicating a serial number indicating a model name of the corresponding monitor is attached, and the data indicated by the bar code label is displayed on the computer 4 by the monitor. It is used in the process of generating.

Hereinafter, the operation of the unique information automatic input system of the monitor of the present invention having the above-described configuration will be described.

In order to automatically input the monitor specific information to the monitor according to the present invention, first, it is required to attach all the barcode labels to a fixed position.

When the assembled and adjusted monitor is loaded on the monitor pallet 3 and transported to the vicinity of the workbench 5 of the computer 4 and reaches a predetermined position, the contact sensor mounted on one side of the computer workbench 5 is reached. 51 senses the arrival of the monitor carriage 3.

As the sensor for detecting whether the monitor carriage 3 has reached a specific position required by the system of the present invention, various sensors such as an optical sensor or a position sensor may be used in addition to the contact sensor 51.

The signal output from the contact sensor 51 sensing the monitor carriage 3 transferred to a specific position is transmitted to the CPU 41 of the computer 4. The CPU 41, which receives the signal output from the contact sensor 51, drives a predetermined mechanical operation unit (not shown) to control the 15-pin D-SUB connector 8 of the computer 4 and the monitor 1. Connect the 15-pin D-SUB connector (9).

The data communication procedure between the computer 4 and the monitor 1 developed after the two connectors are connected will be described in detail as follows.

2 is a host I ² C A timing diagram of an SDA (Signal of DAta) signal and an SCL (Signal of CLock) signal transmitted between the interface unit 46 and the slave DDC IC 11 is shown. FIG. 3 is a flowchart showing the overall procedures of data communication between the computer 4 and the monitor 1.

First, in order to check whether the monitor 1 is connected and whether the monitor 1 can be communicated with, the control of the CPU 41 is controlled. I ² C The interface unit 46 periodically transmits an 8-bit (bit) slave address toward the monitor 1 which is a slave device (step S1).

I ² C The interface unit 46 and the DDC IC 11 are interposed between the computer 4 and the monitor 1. I ² C As it provides a communication environment conforming to the protocol, transmission of data and clock through SDA and SCL I ² C It is performed according to the protocol.

When the D-SUB cable and the 15-pin connectors (8, 9) of both terminals are connected normally, and a communication path is established between the computer (4) and the monitor (1), I ² C The slave address sent out from the interface unit 46 is input to the DDC IC 11.

When the slave address sent to the DDC IC 11 matches the address of the DDC IC 11, as shown in FIG. 2, the DDC IC 11 is configured for the ninth clock. I ² C The LOW signal is transmitted to the interface unit 46. That is, the host I ² C When the interface unit 46 transmits the ninth clock while keeping the SDA high, the DDC IC 11 transitions the SDA synchronized to the ninth clock to the LOW state.

I ² C The interface unit 46 detects such a transition of the signal as an ACK signal, and notifies the CPU 41.

Therefore, the CPU 41 periodically I ² C By checking the interface unit 46 to determine whether the ACK signal is received, it is possible to confirm whether a communication path is established between the computer 4 and the monitor 1 (S2).

I ² C If the ACK signal is not received by the interface unit 46, the operation of transmitting the slave address to the slave device is continued. However, when the ACK signal is received, not only the monitor 1 is connected to the computer 4 but also the monitor 1 is in a communicable state. The drive control signal is transmitted to the barcode reader 6.

In addition, the CPU 41 drives a separate mechanical component (not shown) to access the barcode reader 6 to a barcode label attachment point outside the monitor 1.

As the barcode reader 6 approaches the barcode label attachment point, the barcode reader 6 can scan the barcode without difficulty. When the barcode is scanned, the barcode reader 6 transmits the barcode information to the CPU 41 via the RS-232C interface 44 (step S3).

The CPU 41 which has received the barcode information determines whether the input barcode information is normal data. That is, it is determined whether the barcode reader 6 has scanned the barcode correctly, and whether the scanned barcode information is not lost in the process of being transmitted to the CPU 41 (step S4).

If it is determined that the barcode information is abnormal in the determination process, the CPU 41 outputs an error message through a separate display means (not shown) provided in the computer 4 (step S9).

However, if no error is detected in the scanned barcode information, the CPU 41 reads the product information file stored in the RAM 43, combines the contents recorded in the product information file with the barcode information, and monitors unique information. Generate (S5 process).

When generation of the unique information is completed, the CPU 41 starts a job of transmitting the unique information to the monitor 1. Under the control of the CPU 41 I ² C The procedure of transmitting the monitor specific information between the interface unit 46 and the DDC IC 11 will now be described.

As shown in FIG. 2, I ² C When the SDA is changed from HIGH to LOW while the logic state of the SCL is HIGH by the interface unit 46, the transition of the logic state means the start of data transmission. From the next clock, the monitor specific information is transmitted to the DDC IC 11 via the SDA signal line in synchronization with the clock.

like this, I ² C The monitor specific information transmitted from the computer 4 to the monitor 1 based on the protocol is stored in the RAM 12 of the monitor 1 by the DDC IC 11 (step S6).

When the transmission of the monitor unique information is finished I ² C The interface unit 46 transitions the SDA from LOW to HIGH while the logic state of the SCL is HIGH to inform the DDC IC 11 that transmission of the monitor unique information is completed.

I ² C The DDC IC 11 notified of the completion of the data transmission from the interface unit 46 sends a signal indicating whether the operation of storing the monitor unique information in the RAM 12 is normally completed. I ² C Reverse transmission to the interface unit 46.

I ² C The interface unit 46 determines whether or not the unique information is normally stored in the RAM 12 based on whether the signal is received.

If the unique information is not normally stored in the determination process, the DDC IC 11 notifies the CPU 41 of the computer 4 that the storing operation of the monitor unique information has not been completed normally.

As a result of the determination, when it is determined that the unique information storing operation is normally completed, the CPU 41 transmits a drive control signal to the monitor transfer device operator 7 via the monitor transfer device interface 45. The monitor transfer device operator 7 receiving the control signal from the CPU 41 drives the monitor transfer device 2 to transfer the monitor 1 to the working position of the next process (step S8).

However, if the storage of the unique information is not smoothly performed, an error message is displayed through a separate indicator or an alarm is generated in a manner similar to that of a barcode reading error.

When the error message is output in this manner, an operator who can take appropriate measures for the error checks the computer 4 or the monitor 1 to solve the problem, and resumes the monitor-specific information automatic input process.

By the automatic input system of the unique information of the monitor of the present invention, the unique information input process of the monitor performed by the operator's fine operation is performed automatically, so that accidents and losses due to inadvertent operator's carelessness can be prevented as well as input of unique information. Since there is no need to place a fixed worker in the process, labor costs can be reduced to reduce the production cost of the monitor.

Claims (7)

Monitor transfer means for transferring the monitor being manufactured to a work position for each process; And Generates the monitor unique information, inputs the generated monitor unique information to a monitor waiting to receive the monitor unique information, and when the input of the monitor unique information is completed, the monitor transfer means is driven to operate the monitor in the next process. A system for automatically inputting unique information of a monitor comprising a computer for transferring to a position. The method of claim 1, The computer has a barcode reader to scan a bar code attached to one side of the outer surface of the monitor, and the unique information automatic input system of the monitor, characterized in that to attach the data suggestive to the bar code to the monitor unique information. The method according to claim 1 or 2, And the computer is installed on a workbench for supporting and fixing the computer at an altitude equal to that of the monitor loaded in the monitor transfer device. The method of claim 3, wherein One side of the workbench, characterized in that the monitor detecting means for notifying the central processing unit of the computer of the fact that the monitor is approached when the monitor is loaded on the monitor transfer device to a specific position close to the workbench is installed Automatic input system for unique information of monitor. The method of claim 4, wherein And the central processing unit drives the barcode reader to read the barcode when the central processing unit is notified of the access of the monitor. The method of claim 4, wherein When the central processing unit is notified of the access of the monitor, the data input / output unit of the computer is connected to the data input / output unit of the monitor under the control of the central processing unit, thereby establishing a data communication path between the computer and the monitor. Automatic input system for unique information of a monitor. The method of claim 6, The data communication path established between the computer and the monitor I ² C A unique information automatic input system of a monitor, characterized in that to transmit data in accordance with the protocol.