KR100229036B1 - Circuit for stabilizing high voltage in televvision receiver - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

How to identify the state of the monitored device

I. The technical problem that the invention is trying to solve

Understand the status of multiple secondary monitoring target devices.

All. Summary of the Solution of the Invention

The main monitoring target device checks the state of the plurality of sub-monitoring target devices at regular intervals by a real time clock, and stores data corresponding to the state of the plurality of sub-monitoring target devices, and when the predetermined time elapses, the plurality of down-views are sent to the operation system. Transmit the data corresponding to the status of the era imager.

la. Important uses of the invention

The operating system can accurately grasp the state of the monitored device.

Description

{CIRCUIT FOR STABILIZING HIGH VOLTAGE IN TELEVVISION RECEIVER}

The present invention relates to a method for identifying a state of a monitoring target device in an operation system. In particular, the main monitoring target device among the monitoring target devices grasps a state of a plurality of sub-monitoring target devices at predetermined time intervals by a real time clock. The present invention relates to a method for transmitting information corresponding to a state of a sub-monitoring target device.

Typically, a real time clock generates an interrupt when the time is set by the program in the system.

1 is a block diagram of a monitoring target device and an operating system according to a conventional method for identifying a monitoring target device. Although not shown in FIG. 1, the monitoring target device 100 and the operating system 110 are real time clocks, respectively. It has a (real time clock) built in.

Referring to FIG. 1, the operation system 110 includes a control unit 112, a storage unit 114, and a display unit 116. The control unit 112 detects the state of the monitoring target device 100 and transmits data corresponding to the state of the monitoring target device 100 to the storage unit 114. The storage unit 114 stores data corresponding to the state of the monitoring target device 100 received from the control unit 112. The control unit 112 outputs data corresponding to the state of the monitoring target device 100 stored in the storage unit 114 to the display unit 116 according to a user's request.

The conventional method for determining the state of the monitoring target device has a problem of matching the real-time clock embedded in the monitoring target device 100 with the real-time clock built in the operation system 110. That is, the conventional operating system should periodically monitor the real time clock of the monitored device. In addition, in the conventional method of determining the state of the monitoring target device, when 24 hours have elapsed, the monitoring target device 100 adds 15 minutes of data to the data of one day at the time of 24 hours. There is a hassle to move day-to-day data to day-to-day data and leave the current day-to-day data space empty. As described above, the method for determining the state of the conventional monitoring target device is time consuming because the process of identifying the status of the monitoring target device in the operating system is complicated. In addition, there is a problem that the unnecessary load increases in the operating system.

Accordingly, an object of the present invention is to provide a method for simply grasping a state of a monitoring target device in an operation system.

Another object of the present invention is to provide a method for identifying a state of a plurality of sub-monitoring target devices in a main monitoring target device.

Still another object of the present invention is to provide a method for periodically checking the state of the sub-monitoring target devices in the main monitoring target device.

Still another object of the present invention is to provide a method for accurately identifying a state of a plurality of monitoring target devices in an operation system.

The present invention for achieving the above object is a process of receiving data corresponding to each state of the plurality of sub-monitoring target device at a predetermined time interval in the main monitoring target device, and determine whether the plurality of sub-monitoring target devices are normally transmitted. And generating fake data in the case of non-response in which the plurality of sub-monitoring target devices are not normally transmitted, storing data corresponding to the state of the plurality of sub-monitoring target devices, and transferring the data to the operating system. Characterized in that the transmission process.

1 is a block diagram of a management system and a monitoring target device according to a conventional state detection method.

2 is a block diagram showing an operation system and a monitoring target device to which the present invention is applied;

3 is a view showing a control flow for identifying a state of a monitoring target device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings according to a specific embodiment of the present invention will be described in detail.

FIG. 2 is a block diagram of a monitoring target device and an operating system to which the present invention is applied, and includes a main monitoring target device 100, a plurality of sub-monitoring target devices 101-10n, and an operating system 110. .

Referring to FIG. 2, a monitoring target device for checking and controlling a state in an operating system includes a main monitoring target device 100 and a plurality of sub-monitoring target devices 101 to 10n. The main monitoring target device 100 monitors the plurality of sub-monitoring target devices 101 to 10n at regular time intervals, grasps each state of the plurality of sub-monitoring target devices 101 to 10n, and transmits them to the operation system 110. do.

3 is a diagram illustrating a control flow for identifying a state of a monitoring target device according to an exemplary embodiment of the present invention, wherein the main monitoring target device 100 grasps the states of the plurality of sub-monitoring target devices 101 to 10n, respectively, and operates the system. Transmitting data according to the state of the monitoring target device (110).

2 and 3, in step 300, the main monitoring target device 100 has a current time of ** 00 minutes or ** 15 minutes or ** hours 30 minutes or ** hours by a built-in real time clock. Find out if it is 45 minutes. When the current time is one of ** 00 minutes or ** 15 minutes or ** 30 minutes or ** 45 minutes with the built-in real-time clock, the main monitoring target device 100 is configured in step 302. Check each state of the sub-monitoring target devices 101 to 10n. That is, the main monitoring target device 100 grasps the current time point with a built-in real-time clock, and performs a polling operation to check the state of the sub-monitoring target devices 101 to 10n at 15 minute intervals. Separately, the main monitoring target device 100, if the current time determined by the built-in real-time clock is not one of the ** 00 minutes or ** 15 minutes or ** 30 minutes or ** 45 minutes, Keep track of the current time with the built-in real-time clock.

In step 304, the main monitoring target device 100 determines each state of the plurality of sub-monitoring target devices 101-10n to determine whether there is a normal response from the plurality of sub-monitoring target devices 101-10n. That is, the main monitoring target device 100 receives data corresponding to the state from the plurality of sub-monitoring target devices 101-10n and checks the state of the plurality of sub-monitoring target devices 101-10n. When there are no normal responses from the plurality of sub-monitoring target devices 101 to 10n, the main monitoring target device 100 generates fake data in step 306. That is, the main monitoring target device 100 responds to each state information request from the plurality of sub-monitoring devices 101 to 10n during a polling process of checking the plurality of sub-monitoring devices 101 to 10n, respectively. If not, even after repeating the polling process of requesting status information to the plurality of sub-monitoring devices 101 to 10n two to three times, if the plurality of sub-monitoring devices 101 to 10n do not respond, fake data is generated. Create In other words, if the main monitoring target device 100 requests data corresponding to each state from the plurality of sub-monitoring target devices 101 to 10n, and there is no response to the state from the plurality of sub-monitoring target devices 101 to 10n. Fill in the fake data.

In operation 308, the main monitoring target device 100 stores data corresponding to each state of the plurality of sub-monitoring target devices 101 to 10n. In step 310, the main monitoring target device 100 determines whether each state check point of the plurality of sub-monitoring target devices 101-10n is identified by a built-in real time clock. In the case where the state check points of the plurality of sub-monitoring devices 101 to 10n are identified, the main monitoring device 100 checks data corresponding to each state of the plurality of sub-monitoring devices 101 to 10n and the state check in step 312. The time data is transmitted to the operating system 110.

On the contrary, when the state of the state check of the plurality of sub-monitoring target devices 101 to 10n is not known, the main monitoring target device 100 repeats each state of the plurality of sub-monitoring target devices 101 to 10n. Check it. In operation 314, the main monitoring target device 100 determines whether the transmission of the data corresponding to each state of the plurality of sub-monitoring target devices 101 to 10n is completed to the operation system 110. When the transmission of the data is not completed, the main monitoring target device 100 checks the state of the sub-monitoring target devices 101 to 10n and repeats the process of transmitting the data to the operating system 110. In contrast, when the transmission of the data is completed, the main monitoring target device 100 ends the control operation according to the embodiment of the present invention.

As described above, the present invention can accurately grasp each state of a plurality of monitoring target devices in an operation system, and has an advantage of reducing a time delay occurring in the process of identifying a state of the plurality of monitoring target devices.

Claims (3)

In the high voltage stable circuit of a television receiver having a high voltage circuit for generating a high voltage power supply to the anode of the water pipe by using FBT, A high pressure pulse output unit for intermitting the operating power applied to the primary side winding of the FBT according to a high pressure drive pulse generated from the high voltage oscillation unit; An overcurrent detector for detecting an overcurrent state of the operating power supply with a voltage; An ABL current detection unit connected to the ABL terminal of the FBT and detecting a change in the beam current flowing through the secondary winding of the FBT connected to the anode according to a change in brightness of the screen as a voltage output to the ABL terminal; Generates a high voltage control signal having a voltage level corresponding to the increase or decrease of the beam current amount detected by the ABL current detector, and stops the operation of the high voltage oscillator when an overcurrent state of the beam current amount or an overcurrent state is detected by the overcurrent detector. A control signal generator for generating an X-ray protection signal for And a stabilization control unit for adjusting the voltage of the operating power applied to the FBT according to the voltage level of the high voltage control signal. The method of claim 1, wherein when the beam current amount increases as the screen is brightened, the stabilization controller increases the voltage of the operating power according to the high voltage control signal and applies the voltage to the FBT, and the screen is darkened. When the voltage decreases according to the high voltage control signal, the voltage of the operating power is lowered and applied to the FBT according to the high voltage control signal. The method of claim 2, wherein the control signal generator, A photo coupler having a light emitting diode connected to the operation power source in a forward direction through a resistor and first and second light receiving transistors corresponding thereto and outputting the output of the first light receiving transistor as the high voltage control signal; A rectifier connected in parallel to the primary side winding of the FBT and rectifying the primary side power supply of the FBT to supply power to the first and second light receiving transistors; A transistor having a collector terminal and an emitter terminal connected to a connection point between the resistor and the light emitting diode and a ground, respectively, and a base terminal connected to the output terminals of the overcurrent detector and the ABL current detector; Resistors connected in series between the second light receiving transistor and ground; And a Zener diode connected in a reverse direction to a connection point between the resistors to generate the X-ray protection signal when the voltage at the connection point between the resistors is equal to or higher than a reference voltage.