KR0149214B1 - Method for diagnosing itself for ghost canceller unit - Google Patents

Abstract

The present invention relates to a self-diagnostic method of a ghost elimination device, and when a user presses a switch for self-diagnosis, each part of the ghost eliminating device is self-diagnosed and the diagnosis result is displayed on the screen, thereby allowing the user to detect abnormality of the ghost eliminating device. Because it is easy to know, it is easy to cope with an abnormality of the ghost eliminator.

Description

Self-diagnosis method of ghost elimination device

1 is a schematic block diagram of a ghost removing apparatus for implementing the present invention.

2 is a flowchart showing an operation process of self-diagnosing a ghost removing device according to a preferred embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: AD converter 20: FIFO

30: RAM 40: ROM

50: microcomputer 60: filter unit

70: DA converter 80: controller

The present invention relates to a self-diagnostic method of a ghost elimination device, and more particularly, to a self-diagnosis method of a ghost eliminating device capable of self-diagnosing a ghost eliminating device.

While the video signal from the broadcasting station is transmitted, it is reflected by an obstacle such as a mountain or a building and received by a receiving antenna, or reflected without performing impedance matching of a transmission path, thereby forming a multipath channel (MULTIPLE CHANNEL). A phenomenon in which a reflected video signal is weakly superimposed on a television monitor other than the original video signal is called ghost.

As described above, as part of a method for removing ghosts generated by a multipath channel, a ghost removal reference signal stored in a ghost removal apparatus on the receiving side is sent together with a video signal that transmits a ghost removal reference signal from a broadcasting station. The ghost is removed by inspecting the characteristics of the transmission line, and then filtering the received video signal by configuring a filter to compensate for the characteristic.

On the other hand, if there is no ghost it is difficult to determine the operating state of the ghost removal device, when the ghost is very severe, the ghost is not removed, it is not possible to confirm the abnormality of the ghost removal device.

Accordingly, an object of the present invention is to provide a self-diagnostic method of a ghost removing device capable of self-diagnosing the presence or absence of an abnormality of a ghost removing device.

In order to achieve the above object, the present invention calculates a filter coefficient having a reverse characteristic of a transmission path using a transmission side ghost removal reference signal and a reception side ghost removal reference signal, and inputs an image based on the calculated filter coefficient. In the self-diagnostic method of the ghost removal device to remove the ghost by filtering the signal, if the diagnostic signal for self-diagnosis is input based on the user's operation signal, the filter coefficient is set to 1 to filter the input video signal A first comparison step of sequentially recording the filtered video signal and the input video signal in a FIFO and then comparing the two video signals; A first discriminating step of determining that the filter is normal when the two image signals are the same in the first comparing step, and that the filter is abnormal when the two image signals are different; A second comparison step of repeatedly inputting and outputting predetermined data set in RAM in the ghost eliminating device and comparing the input predetermined data with the output predetermined data; A second discrimination step of determining that the RAM is normal when the input predetermined data and the output predetermined data are the same in the second comparing step; and the RAM is abnormal when the input predetermined data and the output predetermined data are different. Wow; After the filtered video signal is passed through the FIFO based on the calculated filter coefficient, the ghost removal reference signal included in the filtered video signal output through the FIFO is evicted to extract the extracted ghost. A third comparing step of comparing a signal with the receiving ghost reference signal; A third judging step of judging that the FIFO is normal if the two ghost removal reference signals are the same in the third comparison step, and that the FIFO is abnormal if the two ghost removal reference signals are different; A storing step of storing the results of the first judging step, the second judging step, and the third judging step in the RAM; It provides a self-diagnostic method of the ghost removal device, characterized in that the display step of displaying the determination result in each determination step on the screen.

Other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic block diagram of a ghost eliminating device for implementing the present invention. The AD converting unit 10, FIFO (FIRST IN FIRST OUT; hereinafter abbreviated as FIFO) 20, RAM 30, ROM 40, the microcomputer 50, the filter unit 60, the DA converter 70, and the controller 80.

In the drawing, the AD converter 10 converts an input video signal into a digital signal, and the FIFO 20 converts a predetermined portion 20H having a ghost removal reference signal among the filtered video signal and the unfiltered video signal. Enter sequentially. The RAM 30 stores the synchronous addition ghost removal reference signal and the self-diagnosis result, and the ROM 40 stores the ghost removal reference signal possessed by the receiver.

In addition, the microcomputer 50 correlates the synchronously added ghost removal reference signal stored in the RAM 30 and the reception side ghost removal reference signal stored in the ROM 40 to calculate channel characteristics. The filter coefficient to compensate the channel characteristics is calculated and transmitted. In addition, the microcomputer 50 generates a control signal for self-diagnosing the ghost eliminating device based on the diagnostic signal, and selects one of the video signal before filtering and the video signal after filtering from the signal input to the FIFO 20. Control the output signal of the F terminal.

In the figure, the filter unit 60 removes the ghost in the input video signal by using the filter coefficient transmitted from the microcomputer 50, and based on the control signal from the microcomputer 50, The filtered video signal is selectively outputted to the FIFO 20.

The DA converter 70 converts the video signal converted into a digital signal into an analog signal, and the controller 80 controls the overall operation of the television. When a user's operation signal is input, a diagnostic signal for self-diagnosis is performed. And a control signal for displaying the self-diagnosis result on the screen.

2 is a flowchart illustrating an operation of self-diagnosing a ghost elimination device according to a preferred embodiment of the present invention. Hereinafter, the operation of the present invention will be described in detail with reference to FIGS. 1 and 2. .

First, when a switch for self-diagnosis (not shown) is pressed based on a user's operation signal, the controller 80 generates a diagnostic signal to the microcomputer 50 (step 205), and the microcomputer 50 based on the diagnostic signal. In order to determine whether there is an abnormality in the filter unit 60, the filter coefficient is set to 1 (step 210) and transmitted to the filter unit 60.

Therefore, the input video signal is filtered by the filter coefficient 1, and the predetermined portion with the ghost elimination reference signal before filtering and the predetermined portion with the ghost elimination reference signal after filtering are based on the output signal of the F terminal of the microcomputer 50. It is sequentially recorded in the FIFO 20 (step 215).

For example, the microcomputer 50 alternately generates a high level signal and a low level signal at predetermined time intervals and outputs the same through the F terminal. When the high level signal is generated from the F terminal, the filter unit 60 generates a high level signal. A predetermined portion with the ghost elimination reference signal before filtering is recorded in the FIFO 20. When a low level signal is generated from the F terminal of the microcomputer 50, the predetermined portion with the ghost elimination reference signal after filtering is filtered in the filter unit 60. It is recorded in the FIFO 20.

In this case, the predetermined time interval described above is an optimal time interval determined by the programmer, and if the program is programmed in the microcomputer 50 so that the high level signal and the low level signal are alternately generated at the determined optimum time interval, the microcomputer 50 For example, after checking a predetermined time interval programmed using an internal timer (not shown) or the like, the high level signal and the low level signal are alternately generated at a predetermined time interval. will be.

Next, the microcomputer 50 synchronously adds a predetermined portion with the ghost elimination reference signal before filtering recorded by the FIFO 20 to evict the ghost elimination reference signal before filtering, and extracts the predetermined portion with the ghost elimination reference signal after filtering. The synchronous addition adds out the filtered ghost removal reference signal and then compares the two extracted ghost removal reference signals (step 220).

As a result of the comparison in step 220, the microcomputer 50 filters the filter unit 60 if the two extracted ghost removal reference signals are the same (step 225), and the filter unit if the two extracted ghost removal reference signals are different. It is determined that 60 is abnormal (step 230) and stored in the RAM 30.

Next, the microcomputer 50 inputs and outputs predetermined data, which is set to determine whether the RAM 30 is abnormal, to the RAM 30 (step 240), and then compares the input predetermined data with the outputted predetermined data. (Step 245).

For example, a value 0 is inputted to the RAM 30 to output the value 0, and a value 1 inputted to the RAM 30 is outputted to compare whether the 1 value is outputted.

As a result of the comparison of step 245, if the input predetermined data and the output predetermined data are the same, the RAM 30 is normal (step 250), and if the input predetermined data is different from the output predetermined data, the RAM ( 30) is determined to be abnormal (step 255) and stored in the RAM 30.

Next, in order to determine whether there is an abnormality in the FIFO 20, the microcomputer 50 calculates the filter coefficients using the transmission side ghost removal reference signal and the reception side ghost removal reference signal, and then calculates the calculated filter coefficients using the filter unit ( 60, and the filter unit 60 filters the input video signal.

On the other hand, the microcomputer 50 transmits a low level signal to the filter unit 60 through the F terminal after step 260, and accordingly, the filter unit 60 detects a predetermined portion of the ghost removal reference signal after the filtering by the FIFO 20. By providing to the FIFO 20, a predetermined portion with the ghost removal reference signal after filtering is recorded (step 265).

The microcomputer 50 receives a predetermined portion with the ghost elimination reference signal from the FIFO 20, and then synchronously adds for a predetermined time to extract the ghost elimination reference signal after filtering, and then removes the receiving side ghost stored in the ROM 40. Compare with the reference signal (step 270).

As a result of the comparison in step 270, the microcomputer 50 indicates that the FIFO 20 is normal if the two ghost removal reference signals are the same (step 275), and the FIFO 20 is abnormal if the two ghost removal reference signals are different ( Step 280 is determined and stored in the RAM 30.

Next, when the microcomputer 50 outputs the determination results of the FIFO 20, the RAM 30, and the filter unit 60 stored in the RAM 30 to the control unit 80, the display of the control unit 80 is displayed. The discrimination result is displayed on the screen based on the control signal (step 285).

Accordingly, the self-diagnosis result is displayed on the screen based on the control signal of the controller 80 (step 285).

Therefore, when self-diagnosing the ghost elimination device, when a user presses a switch for self-diagnosis, each part of the ghost eliminating device is self-diagnosed and the diagnosis result is displayed on the screen.

In the embodiment of the present invention, the FIFO 20, the RAM 30, and the filter unit 60 have been determined. However, it will be readily apparent to those skilled in the art that abnormalities can be determined using a diagnostic method for other parts. Could be.

As described above, by using the present invention, it is easy to know whether there is an abnormality in each part of the ghost removing apparatus, so that the convenience of easily coping when the ghost removing apparatus is abnormal is provided.

Claims (1)

Ghost elimination for removing ghosts by calculating a filter coefficient having a reverse characteristic of a transmission path using a transmitting side ghost elimination reference signal and a receiving side ghost eliminating reference signal and filtering an input video signal based on the calculated filter coefficient. In the self-diagnostic method of the device, if a diagnostic signal for self-diagnosis is input based on a user's operation signal, the filter coefficient is set to 1 to filter the input video signal, and the filtered video signal and the input A first comparison step of sequentially recording video signals in a FIFO and then comparing the two video signals; A first discriminating step of determining that the filter is normal when the two image signals are the same in the first comparing step, and that the filter is abnormal when the two image signals are different; A second comparison step of repeatedly inputting and outputting predetermined data set in RAM in the ghost eliminating device and comparing the input predetermined data with the output predetermined data; A second discrimination step of determining that the RAM is normal when the input predetermined data and the output predetermined data are the same in the second comparing step; and the RAM is abnormal when the input predetermined data and the output predetermined data are different. Wow; After the filtered video signal is passed through the FIFO based on the calculated filter coefficient, the ghost removal reference signal included in the filtered video signal output through the FIFO is evicted to extract the extracted ghost. A third comparing step of comparing a signal with the receiving ghost reference signal; A third judging step of judging that the FIFO is normal when the two ghost removal reference signals are the same in the third comparison step and that the FIFO is abnormal when the two ghost removal reference signals are different; A storing step of storing the results of the first judging step, the second judging step, and the third judging step in the RAM; Self-diagnosis method of the ghost removing device characterized in that it comprises the step of displaying the determination result in each determination step on the screen.