KR0130818B1 - Gcr signal distinction method and apparatus - Google Patents

Abstract

Disclosed is a GCR signal discriminating method including a first step which initializes each parameter of the discriminating steps, a second step which increases the number of set field in the initializing step and detects a GCR line existing at the field, a sampling data test step which discriminates whether an absolute error value between neighboring two sampling data about the detected GCR line is detected more than a predetermined number as a larger value than the reference value, a third step which judges the corresponding GCR line as a GCR signal when the absolute error value larger than the reference value is detected more than the predetermined number, a fourth step which judges the corresponding GCR line as a pedestal signal when the absolute error value larger than the reference value is detected less than the predetermined number, and a fifth step which checks the field number so that the previous steps are repeatedly performed on each step for the field section of a predetermined number. Thus, it is discriminated whether the GCR signal of the checked 8 fields are correct GCR signal.

Description

GCR signal discrimination method and device

1 is a basic waveform diagram constituting a conventional GCR signal.

2 is a basic waveform diagram constituting a GCR signal used in the present invention.

3 is a waveform diagram showing a GCR signal used in the present invention.

4 is a block diagram showing an embodiment of a GCR signal discrimination apparatus according to the present invention.

5 is a flowchart showing an embodiment of a GCR signal discrimination method according to the present invention.

* Explanation of symbols for main parts of the drawings

11: delay unit 13: absolute part

14,16: comparator 15: counter

17: Register 18: DSP

The present invention relates to a method for discriminating a GCR (Ghost Canel Reference) signal included in a TV video signal. In particular, the present invention relates to a GCR line that exists in each field for a GCR signal composed of a plurality of field units. The present invention relates to a GCR signal discrimination method and apparatus for discriminating the shape of each GCR line by inspecting sampling data and discriminating the GCR signal according to the result.

As the current TV broadcast signal is a terrestrial broadcast signal, the signal is distorted by the reflection of the transmission signal by the reflector, the distortion caused by the non-ideal channel characteristics of the air, which is the transmission medium, and the additional noise. As a TV broadcast signal passes through a multipath channel, a time delay difference and attenuation of a signal occur along a path, and as a result, a ghost phenomenon occurs in which a plurality of images are superimposed on one screen. This ghost phenomenon has a greater impact on image quality than other additive noises.

In particular, more serious problems may occur in the case of information service media such as text multiplexing. That is, if a transmission code is misinterpreted as another code by a ghost signal, wrong letters or figures appear. The research on the technology for eliminating such ghost phenomenon is progressing steadily, and one of them is to carry a predetermined GCR signal together when transmitting the TV signal and to transmit the signal by detecting the GCR signal at the receiver side. Research has been conducted on a technique for removing ghost components by analyzing the distortion degree of.

First, the transmitter inserts and sends a predetermined GCR signal to a TV video signal to be broadcast. FIG. 1 shows a fundamental waveform of a GCR signal conventionally used. (A) of FIG. 1 is a GCR waveform which has a predetermined magnitude | size, and (b) shows a pedestal waveform. These two fundamental waveforms are inserted in a predetermined position in each field of the TV video signal with a certain rule. That is, the two basic waveforms constituting the GCR signal are inserted into 18H and 281H, which are vertical blanking periods of the video signal, respectively. The GCR signal is composed of eight fields as one unit.

However, in the conventional GCR signal discrimination method, since the S / N ratio of the GCR signal is low, there is a problem that false detection occurs due to noise components when the receiver detects the GCR signal included in the TV video signal.

Accordingly, an object of the present invention is to provide a method for more accurately determining a GCR signal from a TV video signal transmitted by inserting a new GCR signal having an improved S / N ratio.

Another object of the present invention is to provide an apparatus for more accurately determining a GCR signal from a TV video signal transmitted by inserting a new GCR signal.

An object of the present invention as described above is a method for determining a GCR signal included in a TV video signal, the method comprising the steps of initializing each variable of the discrimination process, increasing the number of fields set in the initializing step and then present in the field. Detecting a GCR line, a sampling data inspection step of determining whether an error absolute value between two adjacent sampling data for a detected GCR line is detected more than a predetermined number of times as a value larger than a predetermined reference value, and an error absolute value larger than the reference value Determining the GCR line as a GCR signal when the predetermined number of times is detected or more, and Determining the corresponding GCR line as the pedestal signal when an absolute error value larger than the reference value is detected below the predetermined number of times and the above-described steps This is accomplished by checking the number of fields to be performed repeatedly for each field during the field period of.

Another object of the present invention is to provide an error between the two sampling data supplied from the switch and a switch in which switching is controlled by a control signal by receiving sampling data of a GCR line existing between predetermined horizontal driving mechanisms of each field as one terminal. An absolute absolute value generator for calculating an absolute value, a comparison discriminator for determining whether an absolute absolute value of a predetermined size or more is detected a predetermined number of times by receiving an absolute absolute value from the error absolute value generator, and for a predetermined number of fields. Generates a control signal that controls the switching of the switch by receiving the output signal of the GCR discriminator and a predetermined test interval code, comparing the output of the comparator with a predetermined standard GCR signal and outputting a different signal as a result. Is achieved by a logic operation unit.

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

2 shows the fundamental waveforms of the GCR signal used in the present invention. (A) of FIG. 2 shows an S-GCR waveform, (b) shows an SC-GCR waveform, and (c) shows a pedestal waveform. The S-GCR waveform and the SC-GCR waveform are random data streams each consisting of a predetermined number of data, and have a complementary relationship with each other. A CS-GCR (Complem entary Sequence-GCR) signal consisting of these waveforms is shown in FIG. As shown, the GCR signal is composed of eight fields as one unit, and the waveforms (a), (b) and (c) in FIG. 2 are inserted one after another with a predetermined rule in a predetermined scan line of each field.

In addition, signals having arbitrary fixed waveforms (A +, A-, B +, and B-) are inserted in the scanning lines before the scanning lines into which the GCR signals are inserted, and cancel each other when detecting the GCR signals.

4 shows an apparatus for detecting and discriminating such a GCR signal. The apparatus of FIG. 4 has a delay for delaying the switch SW to which data DGCR of the GCR line is applied to one terminal a and the data supplied from the other terminal b of the switch SW by one sampling period. An output value of the adder 12 and the adder 12 that calculates a difference between the sampling data S1 supplied from the switch SW and the sampling data S1 + 1 supplied from the delay unit 11; In the first comparator 14 and the first comparator 14 for comparing the absolute value 13 for absolute value of the absolute value 13, the absolute value ABS supplied from the absolute value part 13, and the predetermined first reference value TH1. A counter 15 for counting when a predetermined value is output, a second comparator 16 for comparing the output of the counter 15 with a predetermined second reference value TH2, and a second comparator 16 for a predetermined field section. Compares the data stored in the register 17 and the standard GCR data with the register 17, and outputs the result, and the DSP (Digital Signal Processor; D) 18) and an OR gate 19 for generating a control signal for controlling the on / off of the switch SW by OR-operating the output of the DSP 18 and the test section signal SCHK. do.

In FIG. 4, the GCR line data DGCR applied to one terminal a of the switch SW is GCR data inserted into a predetermined scan line of each field as shown in FIG. The GCR line can be selected using a synchronous detector (not shown) and a counter (not shown). For example, if the GCR line is on the 18th line of the field, the vertical sync signal should be counted and the horizontal sync signal should be counted. If the GCR line is on the 18th line, the vertical sync signal is counted and the horizontal sync signal is counted. The GCR line of the 18th line can be selected by generating a predetermined pulse in the horizontal synchronization signal. The switch SW receiving the selected GCR line data DGCR transmits the GCR line data to the delay unit 11 in the on / off state by the control signal CTL. At this time, the turn-on of the switch SW coincides with the start of the inspection section for the GCR line data DGCR. The inspection section is determined by the inspection section signal SCHK applied to one pressure terminal of the OR gate 19. For example, when sampling a TV image preference at a frequency of 4 fsc, one gaze line has about 910 sampling values. Therefore, if the section to be examined is 450 to 482 sampling sections of the GCR line data, it is assumed that the switch SW is turned on when the control signal CTL is at a low level during the corresponding section. The inspection section is determined by applying the inspection section signal SCHK. As such, the GCR line data supplied through the switch SW is delayed by one sampling interval in the delay unit 11. Then, the trailing device 12 obtains a difference between the sampling data S1 supplied from the switch SW and the sampling data S1 + 1 supplied from the delayer 11 by being delayed by one sampling period. The difference between the two sampling data S1 and S1 + 1 obtained by the adder 12 is converted into an absolute value ABS in the absolute value portion 13 and supplied to the first comparator 14. The first comparator 14 compares the absolute value ABS with the first predetermined reference value TH1.

Here, the first reference value TH1 is a data size for distinguishing whether the data of the test section is the data of the GCR signal or the data of the pedestal signal, and the value is experimentally calculated. For example, when the sampling data of the GCR line is 8-bit data, the first reference value TH1 obtained experimentally is about eight.

The first comparator 14 outputs 1 when the absolute value ABS is greater than or equal to the first reference value TH1 and 0 when the absolute value ABS is less than or equal to the first reference value TH1. Then, the counter 15 uses the output of the first comparator 14 as the clock CLK to increase the counting value CNT and increase the value by one each time 1 is supplied from the comparator 14. It is supplied to the comparator 16. The second comparator 16 compares the counting value CNT supplied from the counter 15 with the second reference value TH2, and outputs 1 when the counting value CNT is greater than or equal to the second reference value TH2. If it is, output 0. Here, the second reference value TH2 is a predetermined reference number for determining the corresponding GCR line as the GCR signal when an error between adjacent sampling data is more than a certain number of times when the data of the test section is the data of the GCR signal. It is calculated experimentally like (TH1). The register 17 divides and stores the GCR line under test into a GCR signal or a pedestal signal according to a logic value supplied from the comparator 16. That is, if the output of the comparator 16 is 1, the register 17 stores the GCR line under test as a GCR signal, and if the output of the comparator 16 is 0, the register 17 stores the GCR line under test as a pedestal signal. do.

In this way, the GCR line of each field is determined as a GCR signal or a pedestal signal, and the result is stored in the register 17 repeatedly for each of the eight fields. When the determination of the GCR lines for the eight fields is completed, the GCR line determination results for the eight fields stored in the register 17 are transmitted to the DSP 18. Then, the DSP 18 compares the GCR line determination result of the eight fields supplied from the register 17 with the standard GCR signal stored in advance, and determines whether the GCR signal of the eight fields found is the correct GCR signal. The DSP 18 outputs 1 if the GCR signals of the eight fields searched match the standard GCR signal, and 0 if they do not match. When 1 is output from the DSP 18, the control signal CTL, which is the output of the OR gate 19, is at a high level, so that the switch SW is turned off and remains off until the next test section is started. On the other hand, if 0 is output from the DSP 18, the control signal CTL, which is the output of the OR gate 19, is at a low level, and keeps the switch SW on. Perform determination of the GCR line again.

5 is a flowchart illustrating an example of a GCR signal discrimination method according to the present invention.

First, the variables used to perform detection and discrimination of the GCR signal are initialized (111). In other words, the sampling position (I) of the sampling section (I ₁ to I ₂ ) for use in discriminating the GCR signal among the sampling data of the GCR line existing at the predetermined position of each field is designated as the position (I) of the first sampling value. , The number of fields X and the counter CNT are respectively set to zero. Then, the number of fields X is increased by one (112), and the scanning line LG corresponding to the GCR line among the scanning lines of the field X is detected (113). Then, the absolute absolute value of the first sampling value SI and the I + 1st sampling value SI + 1 of the detected scan gun is compared with the predetermined first reference value TH1 (114). As a result of the comparison, when the absolute value difference is larger than the first reference value TH1, the counting value CNT is increased by one (115), and the sampling position (1) is also increased by one (116). On the other hand, if the absolute absolute value is less than or equal to the first reference value TH1, the counting value CNT is increased by one without increasing the counting value CNT (116). Then, the increased current sampling position 1 is compared with the position I2 of the last sampling value of the sampling interval (117). If the current sampling position (1) is not larger than the last sampling position (I2) as a result of the comparison, comparing the absolute absolute value of the two sampling values (SI, SI + 1) previously executed with the first reference value (TH1) Execute (114) again. On the other hand, if the current sampling position I is greater than the last sampling position I2 as a result of the comparison, the counting value CNT increased in the previous step 115 is compared with the second reference value TH2 (118). As a result of the comparison, when the counting value CNT is larger than the second reference value TH2, the inspected GCR line is determined to be a GCR signal (119). If the counting value CNT is not greater than the second reference value TH2, the examined GCR line is determined to be a pedestal signal (120). Then, compare the current field number (X) is greater than 8 (121). If the field number (X) is not greater than 8, increase the field number (X) by 1 (112) for the GCR line of the field. If the number of fields X is greater than eight, the inspection is completed for eight fields which are structural units of the GCR signal. When the inspection of the GCR lines for the eight fields is completed as described above, the inspection result of the GCR lines of each field is compared with the standard GCR signal to determine whether the inspected GCR signals of the eight fields are correct GCR signals.

As described above, the method and apparatus for determining a GCR signal according to the present invention determine whether data inserted into a GCR line existing in a predetermined scan line of each field for eight fields is a pedestal signal, which is a GCR signal. The GCR signal can be determined more accurately and effectively by setting a predetermined inspection interval for the data and performing a predetermined operation and comparison process on the sampling data existing in the interval.

Claims (10)

A method for discriminating a GCR signal included in a TV video signal, the method comprising: initializing each variable of the discrimination process, increasing the number of fields set in the initializing step, and then detecting a GCR line existing in the field. And a sampling data inspection step of determining whether an error absolute value between two adjacent sampling data for the detected GCR line is detected more than a predetermined number of times as a value larger than a predetermined reference value, and an error absolute value larger than the reference value is a predetermined number of times or more. Determining a corresponding GCR line as a GCR signal when detected; determining a corresponding GCR line as a pedestal signal when an absolute error value larger than the reference value is detected less than a predetermined number of times; Checking the number of fields to be performed repeatedly for each field during the GCR scene. Call discrimination method. 2. The GCR signal according to claim 1, wherein the GCR signal has a predetermined regularity with a pair of data strings and a magnitude signal as complementary relations, and a predetermined number of fields as one completion stage. A GCR signal discrimination method characterized by being inserted in turn into one scanning line of each field. The GCR according to claim 1, wherein the initializing step sets the number of fields and the counting value to 0, and sets the sampling data position 1 of the inspection target to the first sampling data position I1 of the inspection section. Signal discrimination method. The method of claim 1, wherein the sampling data inspection step comprises: comparing an error absolute value and a predetermined reference value between two adjacent sampling data in a predetermined inspection interval set for the detected GCR line; Increasing the counting value (CNT) and the inspection sampling position (I) if the reference value is larger than the reference value; increasing the inspection sampling position (I) only if the absolute absolute value is not greater than the reference value in the comparing step; Comparing the final sampling position (I2) between the position (I) and the inspection interval; and comparing the absolute absolute value and the reference value if the inspection sampling position (I) is not larger than the final sampling position (I2) in the comparing step. And comparing the counting value CNT with a predetermined reference value TH2 when the inspection sampling position I is greater than the final sampling position I2 in the comparing step. How to determine the GCR signal is characterized. A device for discriminating a GCR signal included in a TV video signal, comprising: a switch receiving sampling data of a GCR line existing in a predetermined horizontal dynamic range of each field as one terminal and switching controlled by a control signal; An error absolute value generator which calculates an absolute value of the error between two adjacent sampling data supplied from and an error absolute value supplied from the error absolute value generator to determine whether an error absolute value of a predetermined size or more is detected a predetermined number or more times A GCR discriminating unit which compares the comparison discriminating unit, the output of the comparing unit for a predetermined number of fields with a predetermined standard GCR signal, and outputs a signal according to the result, and the output signal of the GCR discriminating unit and a predetermined inspection interval. GCR signal discrimination comprising a logic operation unit for receiving a signal and generating a control signal for controlling the switching of the switch Value. 6. The GCR signal according to claim 5, wherein the GCR signal has a predetermined structure with a pair of data strings and one magnitude signal as complementary relations, and a predetermined number of fields as one completion unit. A GCR signal discrimination apparatus which is inserted in turn into one scanning line of each field. 6. The apparatus of claim 5, wherein the error absolute value generator is configured to delay a sampling data supplied from the switch by a predetermined sampling period, and an adder for calculating a difference between the output data of the delayer and the sampling data supplied from the switch. And an absolute value unit for converting the output value of the adder into an absolute difference. The apparatus of claim 5, wherein the comparison discriminating unit is supplied with a first comparator comparing the absolute value supplied from the absolute value unit with a predetermined first reference value and an output signal of the first comparator, and the comparison result is greater than or equal to the first reference value. And a second comparator for comparing a counting value of the counter with a second reference value and outputting a result thereof. The method of claim 5, wherein the GCR discriminator is supplied with the output signal of the second comparator, and if the counting value is greater than the second reference value in the second comparator determines the corresponding GCR line as a GCR signal, and stores the count value is the second If it is less than the reference value, the register which determines and stores the corresponding GCR line as a pedestal signal, compares the result of the determination of the GCR line of each field stored in the register with the data of the GCR line of each field of the standard GCR signal stored in advance. And a processor for outputting an active signal when two GCR data are the same. 6. The logic circuit of claim 5, wherein the logic operation unit receives an output signal of the processor and a predetermined test interval signal to turn on the switch when the test interval starts and to turn off the switch when the output signal of the processor is active. GCR signal discrimination apparatus, characterized in that for generating a control signal.