DE1935213C3 - Circuit for recording and reproducing a color television signal - Google Patents

Description

11. Circuit according to claim 1, characterized in that that the switch (3) during recording without additional identification pulses by line frequencies Pulse (10) is switched from line to line (Fig. 4).

12. Circuit according to claim 1 i, characterized in that that during playback to set the correct switching phase of the switch (18) the color sync signal is used in front of the delay lines (16, 17) or at the output of a switch.

13. A circuit according to claim 1, characterized in that operated automatically or by hand Schaltmiitel are provided, the switches (18) in such a way for a black and white reproduction Hold the switch position so that the instantaneous signal is constantly switched to the luminance channel (20) is.

When recording a color television signal according to the NTSC, PAL or SECAM system, there are Difficulties because the color carrier carrying the color information is in the upper frequency range of the luminance signal, e.g. at 4.4MHz, and thus outside the recording bandwidth of conventional home storage devices located. To avoid this disadvantage, it is known (British patent specification 9 52 487), alternating line by line to record a luminance signal and two color signals offset from one another in terms of frequency and with a counting delay line the luminance signal and the color signals each in their dead times repeat. This solution requires frequency selective means to separate the two color signals from each other separate. In addition, crosstalk between the color signals occurs easily because they occur at the same time are recorded on a track.

To avoid these disadvantages, it is known (DT-AS 12 56 686) to record the three color signals R, G, B representing the primary colors in a so-called sequence of three lines one after the other and to display them with a series connection of two line delay lines and three switches operated at line frequencies to repeat three signals each in their dead times so that all three are always available. It is also known (DT-AS 12 61 876) to make this sequential recording only for the low frequencies of about 0 to 0.5 MHz and a luminance signal with the high frequencies of, for example, 0.5 to 2.0 MHz in each line to record. This improves the sharpness of the reproduced image because the high frequencies of the luminance signal are always available.

The invention is based on the object of developing this known recording method in such a way that that the circuits for the recovery of a composite color video signal can be simplified from the trisquential signal.

This object is achieved by the invention characterized in claim 1. Further training of the Invention are specified in the subclaims,

In the solution according to the invention, the color difference signals and the luminance signal can be used for reproduction can be recovered with a relatively simple circuit. This circuit is permitted In addition, the FBAS color video signal with the quadrature modulated directly without additional effort Ink carrier, e.g. B. after the PAL type to recover.

The invention is explained below with reference to the drawing. In it shows

F i g. 1 in principle the sequential recording,

F i g. 2 the frequency spectrum,

F i g. 3 a block diagram for the recording,

Fig. 4 Equations to explain the meaning the abbreviations and

F i g. 5 is a block diagram for reproduction.

For the sake of simplicity, the amplitude coefficients of the color signals and color difference signals are omitted from the description. Like Fi g. 4 shows, Y _{7 means} the luminance signal in the range from 0-0.5 MHz, Y _H the luminance signal in the range from 0.5 to 2.0 MHz, Y the entire luminance signal from 0-2 MHz, ß the color signal blue from 0-0.5 MHz, R the color signal red, y the color difference signal ß = Y _T , -Y _T , V the color difference signal R-Vr-

According to FIGS. 1 and 2, the signals YY, β, R are recorded in a tri-line sequential manner in the range of low frequencies of 0-0.5 MHz. In the range of 0.5-2 MHz, the luminance signal Yh containing the high frequencies is recorded in each line .

F i g. 3 shows a circuit for recording. The broadband luminance signal Y is fed to an adder 2 via a line 1. The two color subcarrier frequency color difference signals Fu and Fk z. B. be taken from a PAL runtime decoder (where Fv is generated by phase rotation of ± 90 ° from F ± j _V by changing from line to line), two inputs of a switch 3 are supplied, the third input of which is grounded, and its output to a synchronous demodulator 4 is connected, which is fed by a color carrier regenerator 5. This delivers a video-frequency color signal at the output via a low-pass filter 6, which color signal reaches the adder 2 via a line 7. The output signal of the adder 2 is fed to a recording device 9 via a line 8. The switch 3 is switched by a clock generator 30 by line-frequency pulses 10 at the beginning of each line by one step in the direction of the arrow 11.

The mode of operation is as follows: In line 1, switch 3 is in the position shown and does not feed any signal to demodulator 4. The adder 2 receives only the broadband luminance signal V from the line 1, so that the recording device 9 according to FIG. 1 the signal Y- Yt + Y »is supplied. In line 2, switch 3 is switched on and supplies signal Fn to demodulator 4, which after demodulation in demodulator 4 appears on line 7 as signal U = B-Yr . This results in the line 8 according to FIG. 4 in accordance with FIG. 1 Has Sianal B + Yn. In line 3 the switch 3 is switched one step further and feeds the signal Fy to the demodulator 4, so that the signal R + Yh is in accordance with FIG. 1 on the line 7 according to FIG. With the arrangement shown in FIG. 3, the signal according to FIG. 1 recorded.

F i g. 5 applies to playback. The signal coming from the recording device 9 is in a switch 12 according to the spectrum according to FIG. 2, namely into the constantly present luminance signal Yn and the sequential signal Yt, B ₁ R. The signal Yu reaches an adder 13, the sequential signal is modulated in a modulator 14 onto a color carrier generated in an oscillator 15 and arrives at the color carrier frequency the series connection of two line delay lines 16, 17 to which a switch 18 is connected. The oscillator 15 can be identical to the freely oscillating carrier regenerator 5 of the receiving part (FIG. 3). The phase position of the line delay lines 16, 17 is, as in the conventional PAL decoding circuits, a multiple of half the color carrier period. The switch 18 is controlled by line-frequency pulses 10 from the clock generator 30 and operates like the device described in DT-AS 12 56 686. As a result, the three signals shown are constantly generated at outputs 19, 20, 21 in the form of color subcarrier frequencies. In a subtraction stage 22, the signal from the output 20 is subtracted from the signal at the output 19, whereby the signal Fu arises at the output of the subtraction stage 22. In the same way, the color subcarrier-frequency signal Fv is produced at the output of a subtraction stage 23. This is in a phase switch 24, whose phase rotation for the color carrier frequency is switched from line to line between + 90 ° and -90 ° by a half-line frequency switching voltage 25, an adder 25, which also receives the signal Fu. The color carrier frequency luminance signal from output 20 is also demodulated in a demodulator 26 and combined as video frequency signal Kr in adder 13 with signal Yh to form broadband luminance signal Y , which also reaches adder 25. The adder 25 thus contains the broadband luminance signal Y of 0-2 MHz from the adder 13. The color subcarrier-frequency signals Fu and F ± / v, which together produce the modulated PAL color subcarrier, are added to this. In this way, the complete PAL-FBAS signal is generated at a terminal 28, which can be fed to a color television receiver.

The switch 18 must have the correct switching phase, in addition to the line-sequential incrementation, so that z. B. when the pure luminance signal V comes from the recording device 9, the input of the series circuit 16, 17 is connected to the output 20. If during the recording (Fig. 3) switch 3 without special identifier of each line sync pulse 10 is advanced one step, so z. B. at The synchronization of the switching phase via a circuit 27 takes place during playback. This evaluates the signal at the output 20 thereupon whether it contains a color sync signal. If this is not the case, it is Switching phase correct, because the signal at output 20 must not contain a color sync signal. Is a color burst present, the switching phase of the switching device 18 is corrected via the circuit 27. It it is also possible to use the signals at the outputs 19, 21 for controlling the switching phase of the switch 18

to take advantage of. When the switching phase is correct, the demodulated color sync signal must always be present at output 19 be negative because the burst signal has a negative U component. On the other hand, the demodulated must The color sync signal at output 21 must always be positive. Also the sequence of the color sync signal in the sequential one Signal at the input of the delay lines 16, 17, alternating from line to line zero (Ύ line), negative (line), positive (7? line) is for synchronization suitable for the switching phase. The one in the recording part (FIG. 3) without special identification only of line frequencies Switch 3 switched on impulses is mainly for television standards with divisible by 3 Number of lines (405,525,819) suitable.

The circuit according to FIG. 5 has the advantage that, as a result of the subtraction in stages 22, 23, those in modulator 14 Carrier components introduced cancel each other out and the color carrier frequencies at the outputs of these two stages Signals with a suppressed carrier arise, as is necessary for a PAL color carrier. When the signal at the output 20 no longer contains a sufficient proportion of the color carrier, this can from Oscillator 15 can be added to demodulator 26 via line 30. If the signal at output 20 has a sufficient carrier component, a simple diode rectifier is sufficient as demodulator 26. the Phase switch 24 generates the PAL color sync signal at the same time. because it is the V component of the color carrier frequency signal, including the color sync signal, switches from line to line by 180 °.

An identification, i. H. a certain switching phase for the phase switch 24 is not necessary because the phase switch of the modulated color carrier and the color sync signal take place here with the same phase switch and therefore inevitable are right to each other. After replacing the phase switch 24 with a 90 ° phase rotating member, it would turn on terminal 28 has an NTSC signal.

For correct transmission of the vertical sync signal it is useful to switch the switch 18 over several lines after each field to stop, always in the same position. The number of missed forwardings of the Switch 18 must when the recording switch is running 3 must always be divisible by 3.

If the degree of modulation in the modulator 14 is <1, the demodulator 26 can be a simple amplitude rectifier being.

It can be automatic or manually operated

ϊο Switching elements can be provided which, when a black-and-white recording is played, hold the switch 18 in such a switch position that the instantaneous signal is constantly switched to the luminance channel 20. Then the luminance channel constantly receives the direct luminance signal, since ß = /? = Wist. The color difference signals and thus also the color carrier disappear. The high frequencies of the luminance signal are always present anyway due to the signal Y _H.

For this purpose 2 sheets of drawings

Claims (10)

ι Claims: 1.Circuit for recording and reproducing a color television signal containing a luminance signal and two color signals, in which three signals representing different color components are fed line by line to the recording device by means of a switch operated at line frequencies, and their dead times are repeated during reproduction by means of two line delay lines and line frequency switches , characterized in that the switch (3) is fed in such a way that the recording device (9) alternately receives the luminance signal (Yt) line by line. the first color signal (B) and the second color signal ^ are supplied. 2. A circuit according to claim 1, characterized in that the signals (Yt, B, R) passed through the switch (3) contain only the low video frequencies (0-0.5 MHz) and the high frequencies (above 0.5 MHz) containing luminance signal (Yh) is fed to the recording device (9) in each line. 3. A circuit according to claim 2, characterized in that the recording device (9) constantly a luminance signal (Y) containing the low and high frequencies and via the switch (3) in the first line no signal, in the second line only the low Frequencies (0-0.5MHz) containing first color difference signal (LJ = B-Yt) and in the third line a second color difference signal containing only the low frequencies (V = R-Yt) is supplied (Fig. 3). 4. A circuit according to claim 2, characterized in that during playback to obtain two color difference signals (U, V) containing only the low frequencies, the luminance signal (Yt) containing the low frequencies from the color signal (B = Y) containing the low frequencies _T + UR = Y _T + V) is subtracted (Fig. 5). 5. A circuit according to claim 1, characterized in that during playback the sequential signal taken from the recording device (9) is fed to a series circuit of two line delay lines (16,17), at the beginning, midpoint and end of which three switches (18) each with three inputs are connected in parallel, which are actuated at a line frequency with such a different switching phase that one of the three signals (Yt, B, R) is constantly available at the output of each switch (FIG. 5). 6. A circuit according to claim 5, characterized in that the three signals before being fed to the delay lines (16, 17) are modulated onto a carrier with the color carrier frequency of the system will. 7. A circuit according to claim 4 and 6, characterized in that the subtraction takes place color subcarrier frequency and the so obtained color subcarrier frequency color difference signals (Fu, Fv) with the insertion of a phase rotation (24) switched from line to line between + 90 ° and -90 ° in one the signals are combined to form a modulated PAL color carrier (FIG. 5). 8. A circuit according to claim 7, characterized in that the PAL color carrier with one of the Luminance signal YV) taken from the recording device (9) a complete PAL-FBAS signal is put together (Fig. 5). 9. A circuit according to claim 6, characterized in that the degree of modulation is m <1 and the luminance signal is obtained from the color carrier frequency luminance signal (Fyt) at the output of one switch in an amplitude rectifier (26). 10. A circuit according to claim 7 and 9, characterized in that the formation of the color carrier frequency Color difference signals in the subtraction stages (22, 23) takes place so that the color carrier is suppressed.