JP2545845B2 - Color encoding device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color encoding device, and more particularly to a color encoding device for obtaining an analog carrier color signal from a digital color difference signal.

[Outline of Invention]

In the present invention, the color encoding device has a duty ratio of 1 /
A pair of digital color difference signals of m (m> 1) are serialized by a serialization unit that serializes with a phase difference θ, and the frequency is m fs.
D / A conversion is performed using a clock signal of c / n (where fsc is the color subcarrier frequency, and n is a natural number), and the frequency component in the vicinity of the color subcarrier frequency fsc of the D / A converted output is extracted. The phase difference θ ° is selected as 90 ° × m when n = 1 and n ≧
When it is 2, the pair of clock signals having a phase difference of 90 ° × m and a frequency of m fsc is divided by a dividing ratio of 1 / n and is selected as the phase difference of the pair of clock signals. Then, the carrier color signal is obtained without using the modulation circuit.

[Conventional technology]

Conventionally, digital color difference signals BY, RY to analog N
In order to obtain carrier color signals such as TSC and PAL, the digital color difference signals are D / A converted, the baseband analog color difference signals are obtained via the LPF, and then the carrier signal is orthogonally modulated with both color difference signals. The carrier color signal was obtained.

FIG. 6 shows the digital color difference signals BY, RY in this way.
A color encoding device for obtaining a carrier color signal from the above is shown, which will be described below. In the figure, after the digital color difference signals RY and BY from the input terminals T ₁ and T ₂ are supplied to the D / A conversion circuits (1) and (2) and converted into analog signals, , LPF (3), (4). LPF
The outputs (3) and (4) are baseband analog color difference signals, and the baseband analog color difference signals are supplied to modulation circuits (5) and (6) such as a double balanced modulator.
The color subcarrier is supplied from the oscillator (8a) to the modulation circuit (6) through the 90 ° phase shift circuit (7). Also, the modulation circuit (5)
Is directly supplied to the color subcarrier from the oscillator (8a). Then, the modulated signals of the modulation circuits (5) and (6) are added by the addition circuit (9), and the addition output passes through the BPF (11) whose pass band center frequency is the color subcarrier frequency fsc, The carrier color signal SCS is output to the output terminal T ₃ . An analog color video signal is obtained by adding the carrier color signal SCS and the luminance signal.

[Problems to be solved by the invention]

Since the conventional color encoding device is configured as above, the digital color difference signal is D / A converted and then supplied to the LPF to obtain the baseband analog color difference signal, and the baseband analog color difference signal is obtained. The modulation circuits (5) and (6) for performing modulation by the modulation circuit again are necessary. Therefore, there is a drawback that the circuit scale becomes large when configuring the color encoding device.

The present invention has been made in view of the above drawbacks, and an object of the present invention is to obtain a carrier color signal from a digital color difference signal by omitting a modulation circuit, which can significantly reduce the circuit scale. An encoding device is provided.

[Means for solving problems]

Each of the color encoding devices of the present invention has a duty of 1 /
Sequentializing means (21) for sequentially serializing a pair of digital color difference signals of m (m> 1) with a phase difference θ °, and serializing means (21)
Is supplied, and the frequency is m fsc / n (where fsc is the color subcarrier frequency and n is a natural number), and D /
It consists of a D / A conversion circuit (22) for A conversion and a filtering circuit (23) for extracting frequency components near the color subcarrier frequency fsc of the output of the D / A conversion circuit (22), and the phase difference θ ° is , N = 1, 90 ° × m is selected, and when n ≧ 2, a pair of clock signals having a phase difference of 90 ° × m and a frequency of m fsc is divided by 1 / n. The phase difference between the pair of clock signals obtained by frequency division is selected.

[Action]

According to the color encoding device of the present invention, a pair of digital color difference signals RY and BY having a duty of 1 / m (m> 1).
Are added in advance so as to have a phase difference of, for example, 90 ° × m, A / D converted using, for example, a clock signal whose frequency is equal to the color subcarrier frequency m fsc, and this is supplied to the filtering circuit (23). Then, the carrier color signal is obtained.

〔Example〕

Hereinafter, the color encoding apparatus of the present invention will be described in detail with reference to FIGS. 1 to 5.

First, the digital color difference signals RY and BY are supplied to the D / A conversion circuit used in the present invention, and the data speed at the time of D / A conversion of these color difference signals is the color subcarrier frequency fsc (hereinafter referred to as fsc). ), It is possible to modulate around fsc by setting the same clock signal CS.

Now, the original time continuous color difference signal (original signal waveform) is f (t)
And the Fourier transform is F (w), this represents the frequency spectrum of the original signal f (t) (FIG. 4A). The output of the D / A conversion circuit used in the present invention is equivalent to sampling the original signal f (t) at the speed of fsc. Let g (t) be the signal when this original signal f (t) is sampled with an impulse train of period Tsc (= 1 / fsc),
This is expressed by the following equation.

Where δ is a delta function.

If the Fourier transform of the sampled signal g (t) in equation (1) is G (ω), this is the frequency spectrum of the signal g (t) (Fig. 4B, but the harmonic spectrum in the negative direction is (Omitted) and can be expressed as

Here, the sampling angular frequency is ωsc = 2π / Tsc.
Fourier transform G of the signal g (t) expressed by equation (2)
(Ω) is a sample of the original signal f (t) with an impulse train, but in an actual system, it is sampled with a series of pulses having a hold operation and a pulse width of τ.

Now, let a rectangular pulse signal of pulse width τ be pτ (t),
The Fourier transform is pτ (ω) (as shown in FIG. 4C,
Assuming that the frequency spectrum of the signal P τ (t represents the minus direction is omitted)), the signal h (T) sampled in the sequence of the pulse width τ is expressed as follows.

Here, when the signal h (t) is Fourier-transformed, H (ω) = G (ω) · Pτ (ω) (4)

The Fourier transform H (ω) obtained by the equation (4) is converted into the Fourier transform G (ω) obtained by the equation (2) by the Fourier transform Pτ (ω).
It is equivalent to applying a filter represented by and. When Pτ (ω) is actually obtained, the following equation is obtained.

As is apparent from FIG. 4, when the pulse width τ of the sampling pulse is equal to the period Tsc, that is, at a 100% hold output, the frequency component near the sampling angular frequency ωsc is suppressed, but for example 50% or 25%. A pulse sequence of% duty can have a modulation component in the vicinity of the sampling angular frequency ωsc. Therefore, when this is extracted by the BPF, the color difference signal modulated by the sampling angular frequency ωsc can be extracted.
Incidentally, FIG. 5 shows the output spectrum when the D / A conversion circuit is extracted with a pulse sequence of 50% duty.

Next, let g ′ (t) be the signal obtained when the other original time continuous color difference signal represented by f ′ (t) is sampled at a frequency that is 90 ° out of phase with the previous sampling function. Letting the Fourier transform be G '(ω), these can be expressed as follows, similarly to the above equations (1) and (2).

Equation (7) means that the second harmonic component around ωsc is 90 ° out of phase with respect to equation (2).

As described above, the color difference signal BY is D / A converted at the sampling angular frequency ωsc speed, and the color difference signal RY is D / A converted at the 90 ° phase advanced sampling angular frequency ωsc speed. Harmonic components are extracted as balanced modulation components, and both D / A converted outputs are output to BPF.
Then, if the sum is taken, the NTSC system carrier color signal can be obtained.

Furthermore, the sampling frequency ω for the color difference signal BY is determined for each line.
If the V-axis phase inversion processing is performed by advancing or delaying the phase by 90 degrees alternately from sc, and the color difference signal RY is D / A converted at the speed of the sampling frequency ωsc, the carrier color difference signal for PAL is obtained. can get. However, since the output of the D / A conversion circuit must not be extracted as a pulse sequence with 100% duty,
Normally, it is necessary to select 50% or 25% duty.

By using such a principle, it becomes possible to omit the modulation circuit when converting the digital color difference signal of the speed synchronized with the color subcarrier into the analog carrier color signal.

A concrete configuration of the NTSC color encoding apparatus of the present invention based on the above-mentioned principle is shown in FIG. 1 and will be described below. FIG. 1 shows a system diagram when addition is performed in the area of the digital color difference signal.

In FIG. ₁ , digital color difference signals RY and BY having a duty of 50% are input to the input terminals T ₁ and T ₂ , respectively.
The pair of digital color difference signals are θ (here, 18
Sequentializing means (21) for serializing so as to have a phase difference of 0 °)
Is supplied to. The serializing means (21) includes first and second switching means (21a) and (21b) and a control circuit (21
c), clock oscillator (21d), digital adder circuit (21
e) and the first and second switching means (21a) and (21b) connected to the input terminals T ₁ and T ₂ are controlled by the control circuit (21c), and the digital color difference signal R- Y, B-
For example, while outputting the section data of Tsc / 2 of Y, the data is output so that the respective phase difference θ between the digital color difference signals RY and BY is 180 °, and this output is output to the digital adding circuit. (21e), digitally add it, and add the serialized data to the D / A conversion circuit (22), then the D / A conversion circuit (22)
Output is converted into analog by D / A conversion with a clock signal CS having a frequency of 2 fsc, and the BPF whose pass band center frequency is fsc
(23) is supplied to take out the carrier color signal SCS. In this case, a digital adder circuit (21e) is required, but one D / A converter circuit (22) can be used.

In the configuration shown in FIG. 1, the PAM output to the D / A conversion circuit (22)
Considering the case where the signal has a 50% duty, considering the 25% duty, the hardware configuration can eliminate the digital adder circuit only by using a multiplexer.

2 and 3 show a system diagram and a waveform diagram of such a color encoding device.

In FIG. ₂ , R of the digital color difference signal is applied to the input terminals T ₁ , T ₂ and T _4.
-Y, BY and color difference zero data ZD are input. Figure 3,
In B and C, the digital color difference signals BY and RY are shown. The input terminals T ₁ , T ₂ , T ₄ are connected to a multiplexer (25), which is controlled by a multiplexer control circuit (24) and is also connected to a D / A conversion circuit (22). The output of the D / A conversion circuit (22) is BPF
(23) is being supplied. From the clock oscillator (21d), for example, the clock signal CS shown in FIG.
Is supplied to the D / A conversion circuit (22) and is also supplied to the multiplexer control circuit (24). This clock signal CS causes digital color difference signals RY, B-
Open the multiplexer (25) only for the time of Tsc / 4 of Y,
Color difference signal (BY) ₁ only at Tsc / 4 as shown in FIG. 3E.
Is output to the D / A conversion circuit (22), and zero-color-difference data ZD is output for 3/4 of the period Tsc. The color difference signal (BY) ₁ is output. During Tsc / 4, the zero color difference data ZD is output on the color difference signal RY side, and subsequently the time multiplexer (25) of Tsc / 4 is opened to display the color difference signal (RY) shown in FIG. 3D.
₁ is output to the D / A conversion circuit (22), and 2/4 of the cycle Tsc
At the time of, the color difference zero data ZD is output. Such an operation is performed by the color difference signals (BY) ₂ , (RY) ₂ , (BY) ₃ , (R-
Y) ₃ ..., the color difference signal of 25% duty is obtained at the output side of the multiplexer (25) as shown in FIG. 3F. The waveform of FIG. 3G is obtained at the output of the D / A conversion circuit (22). The output of this D / A conversion circuit (22) is the BPF (2
By passing through 3), the carrier color signal having the waveform shown in FIG. 3H can be obtained.

With such a configuration, the digital adder circuit can be omitted.

〔The invention's effect〕

According to the color encoding device of the present invention, by directly extracting the frequency component around the color subcarrier frequency fsc from the output of the D / A conversion circuit through the BPF, the carrier color signal of the NTSC or PAL system is used by the modulation circuit. It has a feature that it can be taken out without needing to simplify the circuit. Furthermore, it is possible to use only one D / A conversion circuit by serializing it in the digital stage.

[Brief description of drawings]

1 and 2 are system diagrams showing respective embodiments of the color encoding apparatus of the present invention, FIG. 3 is a waveform diagram for explaining the circuit of FIG. 2, and FIG. 4 is a waveform explaining the principle of the present invention. FIG. 5 is a spectrum diagram when the output of the D / A conversion circuit is 50% duty, and FIG. 6 is a system diagram of a conventional color encoding device. (21) is a serializing means, (22) is a D / A conversion circuit, (21c) is a control circuit, (21d) is a clock oscillator, (21e) is a digital addition circuit, and (10) and (23) are BPFs. is there.

Claims (1)

(57) [Claims] 1. A serializing means for serializing a pair of digital color difference signals each having a duty of 1 / m (m> 1) with a phase difference θ °, and an output of the serializing means is supplied, and a frequency is m. A D / A conversion circuit that performs D / A conversion using a clock signal of fsc / n (where fsc is the color subcarrier frequency and n is a natural number), and the color subcarrier frequency fsc near the output of the above D / A conversion circuit The phase difference θ ° is selected as 90 ° × m when n = 1, and when n ≧ 2, the phase difference θ ° is 90 ° × m and the frequency is 90 ° × m. m
A color encoding device, characterized in that a pair of clock signals of fsc are separately selected by a phase difference of a pair of clock signals obtained by dividing by a dividing ratio 1 / n.