KR100219164B1 - Digital video deciding system state - Google Patents

Abstract

Disclosed is a digital video with a state discrimination function of the system. This system consists of ECC (Err or Code Collection) which outputs Sync. Block Error (SBE) flag pulse, counter to count SBE flag pulse, and Micom to determine the state of the system by receiving a count from the counter. It is.

Therefore, the use of such a digital video can be informed to the user after determining the system state, there is an advantage that the user can appropriately deal with any abnormal conditions during use of the digital video.

Description

Digital video with system status determination

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for determining the state of digital video, ie, head foreign matter and tape damage, by using a bit error rate (BER) of digital video.

If you play the recording tape using the existing 8mm VCR, VHS VCR or camcorder, the playback screen will be clear if it is normal playback system and normal tape.

If the playback screen does not come out while watching the video, it is difficult for the user to determine the abnormal state of the video, whether it is due to the foreign matter of the head or the tape.

Accordingly, an object of the present invention for solving such a problem is to provide a device for detecting a bit error rate of the signal picked up by the head to determine the abnormal state of the system and to inform the user.

1 is a block diagram showing a part of a digital video having a state discrimination function of a system using a BER according to the present invention.

2 is a waveform diagram showing an input signal according to a predetermined time.

3 is a flow chart of the FIG. 1 system.

* Explanation of symbols for main parts of the drawings

11: micom 12: pre-amplifier

13: equalizer 14: ECC

15, 30: AND gate 16: reset unit

17: A track counter 18: X counter

19: decoder 20: display unit

50: Error counter terminal

In order to achieve the above object, a feature of the present invention is a digital video, in which a counter and a counter counting an ECC (Error Code Collection) outputting a Sync. Block Error (SBE) flag pulse and a SBE flag pulse. It is to provide digital video with the status discrimination function of the system, including the microcomputer to determine the state of the system by receiving the coefficient.

With reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a block diagram showing a part of a digital video having a state discriminating function of a system using a BER according to the present invention.

As shown in Fig. 1, a preamplifier 12 is connected to a head for picking up a video signal recorded on a tape. An equalizer 13 is connected to the preamplifier 12 for distortion correction of the amplified signal, and an equalizer 13 receives a flag pulse (SBE flag pulse) for an error signal. Output ECC (Error Code Collection) 14 is connected

On the other hand, the microcomputer 11 for controlling the system is connected with a reset unit 16 for outputting a reset (initialization) signal under the control of the microcomputer 11. The reset section 16 is connected to an A track counter 17 that counts any A track. The A track counter 17 is connected with an AND gate 15 for performing an AND operation on the applied pulse signal, and the AND gate 15 has an X counter 18 for counting the output pulses of the Annexite. A decoder 19 for decoding the coefficients of the X counter 18 is connected to the X counter 18, and a plurality of end gates 30 and an error counter terminal 50 are sequentially connected to the decoder 19.

In addition, the display unit 20 is connected to the microcomputer 11 to form a configuration for displaying the state of the digital video to match the signal applied from the error counter terminal 50 to the microcomputer 11.

Let's take a look at the operation of the system consisting of this configuration.

When the tape is inserted into the digital video and the playback key is input, the microcomputer 11 controls the entire system. Thus, the head picks up the video signal recorded on the tape, and the picked up video signal is amplified by the preamplifier 12. The amplified video signal is input to the equalizer 13, and the equalizer 13 corrects a signal having distortion in the input signal. The signal passed through the equalizer 13 passes through a sync block (not shown). The ECC 14 outputs an SBE flag pulse (shown in (a) of FIG. 2) to the AND gate 15 in the signal passing through the synchronization block. This SBE flag pulse is simultaneously applied to one terminal of the AND gate 30. In addition, a pulse of a predetermined period (shown in (b) of FIG. 2) is applied to the AND gate 15 from a clock generator (not shown).

The ECC 14 performs an AND gate operation on the SBE flag pulses for two clock pulses when the video signal passed through the synchronous block is an error-free signal, and the SBE flag pulses for four clock pulses when there is one error signal. 15) In addition, the ECC 14 generates an SBE flag pulse for six clock pulses when two error signals are detected in the video signal, an SBE flag pulse for eight clock pulses when three error signals are detected, and any X error signals. Is detected, the SBE flag pulse is output to the AND gate 15 for 2xX + 2 clock pulses. In the case of blank tape, the SBE flag pulse is not output at all.

As soon as the signal recorded on the tape is picked up, the microcomputer 11 controls the reset unit 16 to initialize the A track counter 17. That is, the reset unit 16 applies a reset signal (shown in Fig. 2C) to the A track counter 17 so as to count tracks of a certain section (random A section) of the tape. In addition, the A track counter 17 receives a head switching signal (shown in (d) of FIG. 2) from the microcomputer 11 to allow two heads to alternately pass through the track. Up to (shown in FIG. 2E), the detectable pulse of the video signal is applied to the AND gate 15 while the track is counted (shown in FIG. 2F).

In this way, three signals are applied to the AND gate 15. That is, the detectable signal of the SBE flag pulse from the ECC 14 ((a) of FIG. 2) and the pulse signal (b (b) of FIG. 2) from the clock generator (not shown), and the image signal from the rotor of the SBE flag pulse 17. ((F) of FIG. 2).

The AND gate 15 performs an AND operation on these three applied signals and outputs the signals to the X counter 18. The pulse of this output signal is shown in (g) of FIG. The X counter 18 then counts the incoming pulses and applies the coefficients to the decoder 19.

That is, when there is no error signal SBE, the X counter 18 counts two pulses (shown first in (h) of FIG. 2). Therefore, the X counter 18 outputs '2' to the decoder 19. The decoder 19 decodes the applied counted number and applies a signal to the other terminal of the corresponding AND gate 30 so that the error counter terminal 50 corresponding to the AND gate 30 is driven.

Decoder 19 then decodes the meaning for the number '2'. That is, the number '2' means when there is no error signal. Thus, the decoder 19 inputs a signal from the AND gate 30 to the other terminal of the first AND gate 31. The first AND gate 31 performs an AND operation on the applied signal and the SBE flag pulse to output a high level signal to the NO error counter terminal 51 of the error counter terminal 50. The microcomputer 11 determines that there is no error signal in the picked-up video signal because there is a signal input to the no error counter terminal 51.

If there is one SBE, four pulses are applied to the X counter 18, which counts four pulses (shown second in (h) of FIG. 2) and the decoder 19 Outputs '4'. The decoder 19 decodes the meaning of the number '4' as having one SBE. After decoding, the decoder 19 inputs a signal to the other terminal of the second and gate 32. The second AND gate 32 performs an AND operation on the applied signal and the SBE flag pulse and outputs a high level signal to the one error counter terminal 52. Therefore, since the microcomputer 11 has a signal input to one error counter terminal 52, it is determined that there is one SBE in the picked-up video signal.

If there are two SBEs, six pulses are applied to the X counter 18, and the X counter 18 counts six pulses and outputs '6' to the decoder 19. The decoder 19 decodes the meaning of the number '6' as having two SBEs. After decoding, the decoder 19 inputs a signal to the other terminal of the third and gate 33. The third and gate 33 performs an AND operation on the applied signal and the SBE flag pulse to output a high level signal to the two error counter terminal 53. Thus, the microcomputer 11 determines that there are two SBEs in the picked-up video signal since there is a signal input to the two error counter terminal 53.

Even if there are three or four SBEs, the microcomputer 11 determines the number of SBEs for the picked-up video signal through the above-described process.

In this way, when there are arbitrary X SBEs, 2xX + 2 pulses are applied to the X counter 18. The counter 18 counts 2xX + 2 pulses and outputs '2xX + 2' to the decoder 19. The decoder 19 decodes the meaning of the number '2 × X + 2' into the case where there are X SBEs. After decoding, the decoder 19 inputs a signal to the other terminal of the sixth and gate 36. The sixth and gate 36 performs an AND operation on the applied signal and the SBE flag pulse to output a high level signal to the X error counter terminal 56. Since the microcomputer 11 has a signal input to the X error counter terminal 56, it is determined that there are X SBEs in the picked-up video signal.

The microcomputer 11 that grasps the data on the SBE thus displays the state of the current playback system on the display unit 20 using an OSD or LCD.

That is, if the signal input is input to the no, 1, and 2 error counter terminals 51, 52, and 53 while the track A is counted, the microcomputer 11 determines that the current regeneration system is in a normal state and is displayed on the display unit 21. And the system performs normal operation. If a signal is constantly input to the 3 error counter terminal 54 or the 4 error counter terminal 55, it is determined that the tape is damaged and is displayed on the display unit 21. If a signal is continuously input to the X error counter terminal 56, which is the maximum error counter terminal, for a predetermined time or more, it is determined as a foreign object of the head and is displayed on the display unit 21.

2 to 1 show data buses. That is, in the case of a normal signal without SBE, data is transmitted after two clock pulses (as shown in (i) of FIG. 2), and when there is one SBE, data is transmitted after four clock pulses (see FIG. j)). In addition, if there are two SBEs, data is transmitted after six clock pulses (as shown in (k) of FIG. 2), and when there are X SBEs, there is no data transmission (shown in (l) of FIG. 2). ).

FIG. 3 is a diagram illustrating an operation flowchart of the illustrated FIG. 1 system. When the key for tape playback (ON) is selected (step 301), the digital video system is operated under the control of the microcomputer 11 (step 302). After performing step 302, the microcomputer 11 outputs the reset signal and the head switching signal to the reset unit 16 and the A track counter 17 (step 303). Therefore, the A track counter 17 starts up to any A track count, and the microcomputer 11 checks whether there is a signal input to the error counter terminal 50 (step 304). If there is no signal input as a result of the check, the microcomputer 11 repeats the system from step 303, and if there is an input signal, the microcomputer 11 is input to the 3 error counter terminal 54 and the 4 error counter terminal 55. Check whether there is a signal (step 305). If there is no input signal at the 3 error counter terminal 54 and the 4 error counter terminal 55, the microcomputer 11 repeats the system from step 303, and if there is an input signal, the microcomputer 11 executes the X error counter. It is checked whether there is an input signal at the terminal 56 (step 306). Thus, if there is no input signal at the X error counter terminal 56, the microcomputer 11 determines that the tape is damaged (step 307), and if there is an input signal, it determines that there is foreign matter in the head (step 308).

As described above, since the system state of the current video is determined and notified to the user, the user has an advantage in that an abnormal state occurs during the use of the digital video.

Claims (7)

There is a digital video, ECC (Error Code Collection) for outputting a Sync. Block Error (SBE) flag pulse; A counter for counting the SBE flag pulses; And a microcomputer for receiving a coefficient from the counter to determine the state of the system. 2. The digital video having a discriminating function of claim 1, wherein the counter counts SBE flag pulses at intervals of an arbitrary tape track interval. The digital video having a discriminating function of a system according to claim 1, wherein the SBE flag pulses are generated in a 2 × SBE number + 2 relationship. The method of claim 1, wherein the microcomputer determines that the tape is in a steady state when a constant of 6 or less is applied from the counter during the period of the track section, and the tape is applied when a coefficient of 8 to 10 is applied. A digital video having a discriminating function of a system, characterized in that it is determined to be in a damaged state and that a head is in a water state when a factor of 12 or more is applied. The digital video having the status discrimination function of claim 1, wherein the digital video having the status discrimination function of the system further includes a display unit which displays the state of the current system under the control of the microcomputer. The system of claim 1, wherein the digital video having a status discriminating function of the system comprises: a decoder for decoding and receiving a coefficient of the counter to output a signal; And a plurality of error counter terminals for receiving an input signal corresponding to the meaning decoded from the decoder and outputting the signal to the microcomputer. The digital video having a status discriminating function of a system according to claim 6, wherein a signal is input to the error counter terminal at an arbitrary tape track interval.