DE2161665A1 - DEVICE FOR RECORDING A COLOR TELEVISION SIGNAL - Google Patents

Description

Device for recording a color television signal.

The recording of a standardized composite color television signal with simple Recording devices with a bandwidth of approx.

2 to 3 MHz is known to cause difficulties because the frequency of the ink carrier with approx. 4.4 Mz outside the recording bandwidth of such devices lies.

To avoid this difficulty it is known (DT-AS 1 256 686), in a so-called sequence of three the three color signals R representing the primary colors, G, B to be recorded line by line one after the other and for playback with a series connection of two line delay lines and with three line-frequency operated switches to repeat these three signals in their dead times. It is there too known (DT-AS 1 261 876), this sequential recording only for the low frequencies from about 0 to 0.5 MHz and a luminance signal with the high frequencies from e.g. 0.5 to 2.0 MHz in each line to record. This triceline sequential Recording requires two line delay lines for T playback.

It is also known (DT-AS 1 412 489), bi-sequentially in one Line n a broadband luminance signal and in the next line n + 1 two Record color signals offset from one another in terms of frequency. As with this solution If the luminance signal is only present in every other line, the image sharpness is reduced reduced in the tile leather gift.

The invention is based on the object of a device for recording to provide a color television signal operating on the bi-sequential type, thus only one line delay line is required for playback, and at the same time has improved sharpness during playback.

This object is achieved by the invention described in claim 1 solved. Advantageous further developments of the invention are specified in the subclaims.

In the solution according to the invention, good image sharpness is achieved, because the available recording capacity both in terms of time and in terms of Bandwidth predominantly for recording that which is decisive for the sharpness Luminance signal is used. The for is only in every second line the lower frequency range of the video bandwidth is less of a decisive factor for image sharpness used for the simultaneous recording of both color signals. Every other line has the full broadband luminance signal, and those in between Lines also have this luminance signal in the higher frequency Area. The color carrier is only available in every other line. This is true the vertical resolution for the color signals is reduced. However, this is not an essential one Disadvantage because the resolution of the color signals in the horizontal direction is already strong is decreased. The luminance signal missing in line n + 1 in the low-frequency Area and the color subcarrier missing in line n can be determined by means of a line delay line can be repeated so that these two signals are completely available for playback are.

The invention is explained below with reference to the drawing.

These show: FIG. 1 the frequency spectrum of the recording according to the invention, FIG. 2 shows a block diagram for the recording, FIG. 3 shows a block diagram for the reproduction and FIG. 4 a diagram of the individual signals.

According to FIG. 1 a, a broadband luminance signal is generated in line n Y recorded from 3 MHz bandwidth. This signal consists of a low frequency Part YT and a higher-frequency part H 'which merge into one another at about 1 Mllz walk. The signal YH is also recorded in line n + 1. Instead of YT, however, a color carrier F modulated with two color signals is now recorded. This can be done according to the NTSC, PAL or FAM method with the two color signals be modulated.

In Figure 2, the color signals R, G, B, which are connected to terminals 1, 2, 3 stand, the signals Y, R - Y and B - Y obtained in a matrix 4. The signals R - Y and B - Y are in a modulator 5 one in a generator 6 generated carrier modulated in quadrature modulation, the modulated carrier F reaches an adder 7. With a high-pass filter 8, the signal Y becomes that Signal YH is selectively evaluated and fed to adder 7. The signal Y arrives from the matrix 4 via a line 9 to an input of a line-frequency actuated Switch 10, the other input of which via a line 11, the signals F and Y11 are supplied according to Figure 1b. The switch 10 is by a half-line frequency Switching voltage 12 actuated, so that on a recording device 13 from line to Line alternately the signals according to Figure 1 a and Figure 1 b are recorded.

Figure 3 shows the playback circuit for the from the recorder 13 extracted signal. The circuit contains a line frequency through the switching voltage 12 actuated switch 14, a low-pass filter 15 that only allows YT to pass, an adder stage 16, an adder 17, a bandpass filter 18 which only allows the color carrier F to pass through, as well as a polarity reversing amplifier 30. A modulator 19 operated by a generator 20 is fed, is used to convert the frequency of the color carrier F to the standardized Color subcarrier frequency. The signal YT from the low-pass filter 15 is in a modulator 22 modulated onto a carrier generated in a generator 23 and an adder stage 21- supplied, a line delay line 24 together with a line frequency Switch 25 actuated by switching voltage 12 is used to repeat the signals YT and F in the lines where they are not recorded. The A demodulator 26 serves to reconvert the carrier signal T into the video-frequency signal YT Of the The color carrier F on line d is used in a polarity-reversing amplifier 30 is converted into the color carrier -F, which is then fed to an adder 17.

The adder 17 is on the other hand with the complete signal fed on line b. In the adder 17 is the signal in the Line b containing color carrier F extinguished by the color carrier -F, so that only the signal YH according to FIG. 1b is on line c. With this circuit can the color subcarrier F also lie within the signal v, in that the signal YH extends up to extends below the lower sideband of the ink carrier F. In the adder stage 17, the frequency band occupied by the color carrier F is then canceled out, so that then two separate frequency ranges with components of the luminance signal develop. The luminance signal on line c, freed from the color carrier F. YH is: - In the adder 16 the signal from the line e is added that an the line f the luminance signal is now present in each line.

The mode of operation of this circuit can be seen from FIG. 4, where the signals at the individual points a-1 of the circuit according to FIG are shown for five consecutive lines. In the fully extended switch position the switch 14, 25, which corresponds to lines n, n + 2, n + 4, is created on the Line f and thus also the broadband luminance signal Y at terminal 1. The switch 25 supplies the color carrier on the line k via the delay line 24 F of the preceding lines n - 1, n + 1, the luminance signal in the adder 27 Y is added. There is no signal over line j. At the terminal 1 arises so the complete one FBÄS signal. During lines n - 1, n + 1, n + 3 in the dashed switch position arises on line f and thus at terminal 1 first the signal YEI, which is obtained in the adder 17 will. The switch 25 now supplies the signal YO in carrier frequency on line j Form from rows n, n + 2, n +4 via delay line 24. This signal is demodulated in a demodulator 26 and the video frequency thus obtained Signal YT of the adder 27 is supplied.

At the same time, the color carrier recorded in lines n + 1, n + 3 becomes F supplied from the line h via the line k of the adder 27, so that this again the signals YT from lines n, n + 2, n + 4, YH from lines n + 1, n + 3 and F from lines n + 1, n + 3, and the complete again at the terminal Provides composite signal. During the lines n, n + 2, n + 4 the color carrier becomes F from lines n - 1, n + 1, n + 3 after delay by line duration replaced while in lines n + 1, n + 3 the signal YT from lines n, n + 2, after a delay is replaced by line duration. It can be seen that the Terminal 1 the complete EFAS signal with the components YT, YH and F arises, which is a normal color television receiver can be fed.

Claims (10)

Claims Apparatus for recording a color television signal in which the cells are sequential In each case in line n a luminance signal occupying a certain video bandwidth and a signal containing the color information is recorded in line n + 1 are, characterized in that in the line n + 1 in a range of the video bandwidth one with two color signals modulated color carrier (F) and in another area of the video bandwidth components (Y11) of the luminance signal (Y) are recorded. 2. Apparatus according to claim 1, characterized in that the ink carrier (F) is recorded in the lower part of the video bandwidth and in the upper part the video bandwidth the higher-frequency components (YH) of the luminance signal (Y) to be recorded. 3. Apparatus according to claim 1, characterized in that during playback the signal with a line-frequency operated switch (14) each during the Line n a first channel (e, f) carrying the luminance signal and during the line n + 1 is fed to a second channel (b, d) carrying the color information will. 4. Apparatus according to claim 3, characterized in that in the second Channel (b, d) the components (YH) of the luminance signal (Y) are evaluated selectively and added to the first channel additively (stage 16). 5. Apparatus according to claim 4, characterized in that the selective Evaluation of the components (Y11) of the luminance signal (Y) takes place in that the selectively evaluated color subtracts from the total signal of the second channel (step 17 in Fig. 3). 6. Apparatus according to claim 3, characterized in that the first channel (e, f) the components (Ym) of the luminance signal not transmitted in line n + 1 (Y) evaluated selectively with a filter (15), delayed by one line duration (line 24) and then additively to the first channel during line n + 1 (Step 27 in Fig. 3). 7. Apparatus according to claim 3, characterized in that in the second channel (b, d) the modulated color carrier (F) is selectively evaluated with a filter (18), with a line delay line (24) and a line-frequency operated switch (25) is made available in each line and added to the first channel additively (Step 27 in Fig. 3). 8. Apparatus according to claim 6 and 7, characterized in that the during of the line n + 1 non-transmitted components (YT) from the first channel and the modulated color carrier (F) from the second channel to the input of a line delay line (24) are supplied. 9. Apparatus according to claim 6 and 8, characterized in that the dem first channel (e, f) added delayed components from the output of a line frequency actuated switch (25) are removed, the output of which during line n no Signal leads and during row n + 1 to the output of the row delay line (24) is switched. 10. Apparatus according to claim 7, characterized in that the first Channel fed color carrier (F) from the output of a line-frequency operated switch (25) is removed, the during line n with the output of Line delay line (24) and during line n + 1 with the input of the line delay line (24) is connected (Fig. 3).