JPS62265868A - Reference signal generating circuit - Google Patents

Abstract

PURPOSE:To improve performance removing a ghost by generating a digital signal string that has both a frame synchronizing signal and a clock synchronizing signal on the top of the string in a circuit overlapping a reference signal for removing a ghost with a television signal. CONSTITUTION:A selection circuit 4 selects the output of a frame synchronizing signal generating circuit 3 and that of a digital signal string generating circuit 5. A signal overlap circuit 2 overlaps the output of the selection circuit 4 with that of a television signal generating circuit 1. The ghost removal reference signal overlapped during a vertical blanking interval is transmitted as a packet information signal that has interval, a vertical synchronizing signal during a vertical blanking between a color burst signal 23 and a horizontal synchronizing signal 24, and both the frame synchronizing signal 26 and the clock synchronizing signal 25 during a signal string overlap period 22 apart from a vertical equalizing pulse period on the top of the digital signal string 21.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention is designed to reduce the vertical retrace period of a television signal in order to remove group delay distortion, single frequency amplitude characteristic distortion, ghost, etc. that occur during the transmission of a television signal. The present invention relates to a ghost removal reference signal generation circuit for a ghost removal reference signal superimposed on a ghost removal reference signal.

2. Description of the Related Art Conventionally, a differential signal at the leading edge of a vertical synchronization signal has been used as a reference signal for removing ghosts generated during transmission of television signals. (Reference: Onishi et al., "Automatic Ghost Removal from Television Images," NHK Giken Monthly Report, 1953) The reference signal conventionally used will be explained with reference to FIGS. 4 and 5. In FIG. 4, 100 is the leading edge of the vertical synchronizing signal, 101 is a ghost, and 102 is a vertical equalization pulse. 101 is a delayed version of the vertical synchronization signal leading edge 100. FIG. 5 shows a signal waveform obtained by subtracting the leading edge portion 100 of the vertical synchronization signal and the ghost 101. FIG. In the figure, 103 is a difference signal of the leading edge portion 100 of the vertical synchronization signal, and 104 is a difference signal of the ghost 101. Difference signal 103 of leading edge of vertical synchronization signal
A difference signal 104 between the signal and the ghost indicates an impulse response of the transmission system, and is used to remove the ghost.

Furthermore, the Japan Broadcasting Corporation has proposed a ghost removal reference signal (GCR) as shown in FIG. (Reference: Obara et al., A Study on the Reference Waveform for Ghost Removal, TV Technical Report, RE8j-6, 1982.) In the same figure, 1
10 is a bar signal, 111 is a pulse signal, 112 is a color burst, and 113 is a horizontal synchronization signal. Pulse signal 1
11 is used to estimate the impulse response of the transmission system. Further, the bar signal 110 is used to detect the occurrence of sag due to the transversal filter.

Problems to be Solved by the Invention The problem with conventionally using a vertical synchronization signal as a reference signal for ghost removal is that the signal quality of the synchronization signal of a television signal is not as good as that of a video signal such as DG or CP. This is because the parameters indicating signal quality are not guaranteed. Furthermore, the synchronization signal portion of a television signal subjected to RF signal modulation has the highest signal power and is susceptible to nonlinear distortion. Therefore, the correlation between waveform distortion between the video signal and the synchronization signal due to ghosts and the like is not perfect, and when the leading edge of the vertical synchronization signal is used as a reference signal for ghost removal, it is difficult to sufficiently remove ghosts.

Furthermore, in the reference signal for ghost removal proposed by the Japan Broadcasting Corporation, the pulse signal l11 is equivalent to a 1.5T pulse (half width 187
．． 5 ns) pulses are required. (Reference: Ohara et al., System Study of Adapter Type Ghost Canceller, TV Science and Technology Report, 1752-1. 1982) In the case of such a pulse signal, there is a problem of proximity, which is a problem in teletext broadcasting. It is difficult to obtain information for correcting ghosts, group delay distortion, 5-frequency amplitude characteristic distortion, etc. This is because the impulse response to the transmission distortion is expressed as a collection of many pulses in the vicinity of the original pulse. This is because it is difficult to separate the latter pulse from the original pulse.

Also, since it is a single pulse, its signal power is small;
It was easily affected by noise.

Furthermore, even in the time range in which ghosts can be removed, the method using the vertical synchronization signal leading edge lOO as a reference signal,
For ghosts delayed by 1/2 horizontal period or more, it is impossible to determine whether the delayed signal is due to the reference signal or another delayed signal.
This will be explained using FIG. FIG. 7 is a signal diagram showing a delayed ghost of 1/2 horizontal period or more. In the same figure,
+00 is the leading edge of the vertical synchronization signal, 102 is the equivalent pulse, 1
05 is a ghost created by the delay of the equivalent pulse 102. FIG. 8 shows the vertical synchronization signal leading edge 100 and the vertical synchronization signal (goth) 1
FIG. 2 is a signal diagram showing a signal obtained by subtracting 05. In the figure, 103 is a differential signal of the leading edge portion 100 of the vertical synchronization signal;
6 is a difference signal of the ghost 105. From FIGS. 7 and 8, it is not possible to distinguish whether the ghost 105 is a ghost caused by the equivalent pulse 102 or whether it is caused by two ghosts in which the vertical synchronizing signal leading edge 100 is delayed.

Therefore, the ghost removal range of the ghost removal device using the vertical synchronization signal leading edge 100 as a reference signal is at most 1/2.
There is only one period of water. In addition, the standard signal for ghost removal proposed by the Japan Broadcasting Corporation has the following signal format:
Ghosts with a delay time of 16.8 microseconds or more cannot be removed for the same reason as above.

In view of the above-mentioned problems, the present invention uses a digital signal train having a frame synchronization signal and a clock synchronization signal at the beginning of the digital signal train as a reference signal for ghost removal in a television signal. It is also a high-power signal, can eliminate ghosts delayed by 1/2 horizontal period or more, is transmitted under exactly the same conditions as other video signals, and has a frame synchronization signal and a clock synchronization signal at the beginning of the digital signal train. The present invention relates to a reference signal generator for ghost removal that is capable of transmitting packet information signals.

Means for Solving the Problems In order to solve the above problems, the present invention is a circuit that superimposes a reference signal for ghost l-removal in the vertical blanking period of a television signal, and a frame is added to the beginning of a digital signal train. The present invention generates a digital signal train having a frame synchronization signal and a clock synchronization signal.The present invention uses the above-described means to generate a digital signal having a frame synchronization signal and a clock synchronization signal at the beginning of the digital signal train in a television signal. By superimposing columns and using them as a reference signal for ghost removal, the signal has higher power than a single pulse signal, can remove ghosts delayed by more than 1/2 horizontal period, and is exactly the same as other video signals. The present invention provides a reference signal generation circuit for ghost removal, which is capable of transmitting a packet information signal that is transmitted under certain conditions and has a frame synchronization signal and a clock synchronization signal at the beginning of a digital signal sequence.

Embodiment FIG. 1 is a circuit configuration diagram showing an embodiment of a reference signal generation circuit for ghost removal according to the present invention. In the figure, 1 is a television signal generation circuit, 2 is a signal superimposition circuit, 3 is a clock synchronization signal and frame synchronization signal generation circuit, 4 is a selection circuit, and 5 is a digital signal string generation circuit. This operation will be explained below. The selection circuit 4 selects the output of the clock synchronization signal and frame synchronization signal generation circuit 3 and the output of the digital signal string generation circuit 5. A signal superimposition circuit 2 converts the output of the selection circuit 4 into a television signal generation circuit 1.
superimposed on the output of

FIG. 2 is a waveform diagram showing an example of a reference signal for ghost removal superimposed during the vertical retrace period. In the same figure, 2
1 is a digital signal train, 22 is a signal train superimposition period, 23 is a color burst, and 24 is a horizontal synchronizing signal. In this example, the vertical synchronization signal during the vertical retrace period and the signal string superimposition period 2 shown in FIG.
2, a signal train is superimposed as a binary NRZ signal to obtain a digital signal train 21.

Next, a description will be given of how the superimposed digital signal sequence is used as a reference signal for ghost removal.

FIG. 3 is a circuit configuration diagram showing a ghost removal device using a transversal filter as an example of a ghost removal device. In the figure, 11 is a transversal filter, 12 is a tap gain control circuit, and 13 is an error signal train generation circuit. A television signal containing a ghost is processed by a transmission system that generates group delay distortion, frequency amplitude characteristic distortion, ghost, etc., and finally a transversal filter 11 having an inverse characteristic. Ghosts etc. are removed. From this output signal, an error signal train generation circuit 13 generates an error signal train corresponding to waveform distortion due to removal errors such as group delay distortion, single frequency amplitude characteristic distortion, and ghost. The tap gain control circuit 12 uses the error signal train and the human input signal of the transversal filter 11.
The transversal filter 11 is controlled using an algorithm such as the least square error method so that the error signal sequence is minimized, that is, the group delay distortion 1 frequency amplitude characteristic distortion, ghost, etc. are removed. .

The error signal sequence is obtained by selecting the digital signal sequence, which is a reference signal, from the television signal that has been transmitted and from which the group delay distortion, frequency amplitude characteristic distortion, ghost, etc. have been removed by the transversal filter 11;
It is obtained as a difference between the expected signal sequence corresponding to the selected digital signal sequence that is included in the error signal sequence generation circuit 13 or calculated by the error f3 sequence generation circuit 13.

The power of the digital signal train is greater than the power of a single pulse. Therefore, if the digital signal train is used as a reference signal, it will be less affected by noise than if a conventional flower pulse is used.

Further, the least square error method or the like is used as a control method for the transversal filter 11, and the error signal sequence is correlated with the input signal sequence by 6A to obtain the tap weight correction amount. Even if the signal contains errors due to signals other than the reference signal, the influence can be removed. Therefore, it is also possible to remove ghosts with a delay longer than 1/2 horizontal period.

As described above, according to this embodiment, by using a digital signal string having a frame synchronization signal and a clock synchronization signal at the beginning of the digital signal string as a reference signal for ghost removal, a signal with higher power than a single pulse signal can be generated. In addition, it is possible to remove ghosts delayed by more than 1/2 horizontal period, and it is possible to obtain a reference signal for ghost removal that is transmitted under exactly the same conditions as other video signals. can be increased.

Effects of the Invention As described above, based on the present invention, a digital signal train having a frame synchronization signal and a clock synchronization signal at the beginning of the digital signal train can be superimposed on a television signal and used as a reference signal for ghost removal. By using a signal with higher power than the Hayabusa pulse signal, and using correlation calculations such as the least square error method, it is possible to remove ghosts delayed by more than 1/2 horizontal period, and under exactly the same conditions as the Ike video signal. This signal serves as a reference signal for ghost removal transmitted in the digital signal sequence, thereby improving ghost removal performance and making it possible to transmit a packet information signal having a frame synchronization signal and a clock synchronization signal at the beginning of a digital signal sequence.

[Brief explanation of drawings]

FIG. 1 is a block diagram in one embodiment of the present invention, and FIG.
The figure is a waveform diagram showing a reference signal for ghost removal of the present invention,
FIG. 3 is a circuit configuration diagram showing a ghost removal device, and FIGS. 4, 5, 6, and 7. FIG. 8 is a waveform diagram showing a conventional ghost removal reference signal. ■・・・Television signal generation circuit, 2...
... Signal superimposition circuit, 3 ... Clock synchronization (word, frame synchronization signal generation circuit, 4 ... Selection circuit, 5 ... Digital signal string generation circuit, 11.・
...Transversal filter, 12...
gain control circuit, 13... error signal string generation circuit, 21... digital signal string, 22...
...Signal string superimposition period, 23...Color burst, 24...Horizontal synchronization signal, 25...
- Clock synchronization signal, 26... Frame synchronization signal. Name of agent: Patent attorney Toshio Nakao (1 person) Figure 1 Figure 2 Figure 3 Figure 4/c. Figure 5

Claims (1)

[Claims] A method for generating a digital signal string having a frame synchronization signal and a clock synchronization signal at the beginning of the digital signal string in a reference signal generation circuit for ghost removal that superimposes a reference signal for ghost removal on the vertical retrace period of a television signal. A reference signal generation circuit for ghost removal, characterized by: