JPH0320198B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a video signal processing circuit, and particularly to a video signal processing circuit used in, for example, a SECAM type color video camera.

(Prior Art) In recent years, with the development of electronic technology, recording of video information has become popular.

When recording video information using a video tape recorder that records video information on a recording medium such as a magnetic tape, a color video camera, for example, may be used as an input video information source. By the way, single-tube type color video cameras are currently the mainstream for consumer use due to reasons such as price and operability.

(Problems to be solved) Converting video information into SECAM format video signals in the single-tube color video camera mentioned above.
Flicker is the main cause of deterioration of the signal-to-noise (S/N) ratio in SECAM single-tube color video cameras.

This flicker is caused by the fact that the SECAM method is a line sequential method in which the (R-Y) color difference signal and (B-Y) color difference signal are switched and transmitted for each scanning line, and the number of scanning lines is an odd number (625). This is caused by.

By the way, in order to reduce the above-mentioned flicker, it has been known that color difference signals transmitted line-sequentially may be averaged and transmitted. A conceivable method for averaging the color difference signals is to delay one color difference signal by one horizontal scanning period and transmit it in addition to the other color difference signal.

However, a glass delay line cannot be used to delay one of the color difference signals (the frequency characteristics of color difference signals range from 0Hz to several hundred Hz, so a glass delay line cannot be used due to the shape). Therefore, it is necessary to use a delay element such as a charge coupled device (CCD), which poses a problem in that the current consumption of the circuit increases. Also, general-purpose encoders cannot be used together (some general-purpose encoders are configured to process NTSC and PAL signals using one encoder; for example, if the modulation method is AM modulation or FM modulation) (There is no general-purpose encoder that processes signals with different modulation methods and different modulation methods.)
There was also a problem.

Therefore, an object of the present invention is to improve the signal-to-noise (S/N) ratio of a video signal by averaging color difference signals and transmitting them line-sequentially.

(Means for solving the problems) In order to solve the above-mentioned problems, the present invention provides a first AM modulation circuit that performs AM modulation on a first color difference signal;
a second AM modulation circuit that performs AM modulation on a second color difference signal; a mixing circuit that mixes the output signals of the first and second AM modulation circuits; and an arithmetic average of the signals supplied from the mixing circuit. an averaging circuit; a separating circuit for synchronously detecting the output signal of the averaging circuit and then outputting it as a line-sequential color difference signal; An object of the present invention is to provide a video signal processing circuit including a signal synthesis circuit.

(Embodiment) The figure is a block system diagram of an embodiment of the video signal processing circuit according to the present invention.

1 is an input terminal to which a (R-Y) color difference signal which is a first color difference signal is supplied, and the (R-Y) color difference signal supplied to input terminal 1 is an AM modulation circuit which is a first AM modulation circuit. 2 and AM modulation circuit 2 at color subcarrier frequency SC ₂ (4.40625MHz, −90°).
After being AM modulated, it is supplied to the mixing circuit 3.

On the other hand, 4 is an input terminal to which a (B-Y) color difference signal, which is a second color difference signal, is supplied. It is supplied to the modulation circuit 5, and the color subcarrier frequency SC ₁ (4.40625MHz, 0°) is supplied to the AM modulation circuit 5.
After being subjected to AM modulation, the signal is supplied to the mixing circuit 3.

2 output from the above-mentioned AM modulation circuits 2 and 5
After the different types of modulation signals (quadrature two-phase modulation signals) are mixed in the mixing circuit 3, they are supplied to the comb filter 6, which is an averaging circuit that arithmetic averages the 1H previous signal and the current signal in terms of voltage level. , and are averaged by a comb filter 6 and supplied to synchronous detection circuits 7 and 8.

Further, the synchronous detection circuit 7 is supplied with a signal having the same frequency and phase as the color subcarrier frequency SC ₂ (4.40625MHz, -90°) from the input terminal 9, and the signal supplied from the comb filter 6. is synchronously detected using the signal supplied from the input terminal 9. Therefore, the terminal A of the switch 11 has an averaged (R
-Y) A color difference signal is supplied.

On the other hand, the synchronous detection circuit 8 is supplied with a signal having the same frequency and phase as the color subcarrier frequency SC ₁ (4.40625MHz, 0°) from the input terminal 10, and the signal supplied from the comb filter 6 is Input terminal 10
Synchronous detection is performed using the signal supplied by the Therefore, the averaged (B-Y) color difference signal is supplied to the terminal B of the switch 11.

The switch 11 is a line switch that is selectively switched for each number of scanning lines. Therefore, from the terminal C of the switch 11, an averaged (R-Y) color difference signal and an averaged (B-Y) color difference signal are output. are output alternately for each scanning line. In other words, terminal C of switch 11
An averaged line-sequential color difference signal is output from the .

Note that the above-mentioned synchronous detection circuits 7, 8 and switch 11 are elements constituting a separation circuit.

The line-sequential color difference signal output from terminal C of switch 11 is supplied to FM modulation circuit 14 via pre-emphasis circuit 12 and low-pass filter (low-pass filter) 13. In the FM modulation circuit 14, the line-sequential color difference signal is converted into a discrimination signal for distinguishing between the (R-Y) color difference signal and the (B-Y) color difference signal in response to the selection change of the switch 11. The color subcarrier frequency is inserted across the line and is then supplied to the FM modulation circuit 14 from the input terminal 10.
The signal is FM modulated using a signal of SC ₁ (4.40625MHz, 0°), and is supplied to a mixing circuit 16 via a bell filter 15, which is a bandpass filter having predetermined characteristics.

On the other hand, a luminance signal Y is supplied to the input terminal 17, and this luminance signal Y is passed through a low-pass filter 18.
is supplied to the mixing circuit 16 via.

The mixing circuit 16 mixes and multiplexes the luminance signal and the line-sequential color difference signal. Therefore, from the output terminal 19
A SECAM format composite video signal is output.

In addition, a pre-emphasis circuit 12, a low-pass filter 13, an FM modulation circuit 14, a bell filter 1
5. Mixing circuit 16, low pass filter 18
This is a component of a known video signal synthesis circuit (decoder; FM modulation circuit that synthesizes SECAM format video signals) for SECAM format video signals.

As described above, it is output from the output terminal 19.
Since the color signal components of the SECAM-based composite video signal are averaged, flicker in a color video camera, for example, is reduced. Therefore, in the embodiment described above, the signal-to-noise (S/N) ratio of the color signal component is improved by 3 [dB].

(Effects of the Invention) Since the present invention is configured as described above, the signal-to-noise (S/
N) The ratio can be improved.

[Brief explanation of the drawing]

The figure is a block system diagram of an embodiment of the video signal processing circuit according to the present invention. 1, 4, 9, 10, 17...Input terminal, 2, 5
...AM modulation circuit, 3,16...Mixing circuit, 6...
...Comb filter, 7, 8...Synchronous detection circuit, 1
1... Switch, 12... Pre-emphasis circuit, 13, 18... Low pass filter (low frequency device), 14... FM modulation circuit, 15... Bell filter, 19... Output terminal.

Claims (1)

[Claims] 1 A first AM modulation circuit that performs AM modulation on the first color difference signal, and a second AM modulation circuit that performs AM modulation on the second color difference signal.
an AM modulation circuit, a mixing circuit that mixes the output signals of the first and second AM modulation circuits, an averaging circuit that arithmetic averages the signals supplied from the mixing circuit, and an output signal of the averaging circuit. a separation circuit that synchronously detects the signal and then outputs it as a line-sequential color difference signal;
A video signal processing circuit comprising a video signal synthesis circuit to which the line-sequential color difference signal and the luminance signal are supplied and outputs a standard video signal.