DE2158218A1 - METHOD AND CIRCUIT ARRANGEMENT FOR PRE-DISTORTION OF A TRICE-SEQUENTIAL COLOR TELEVISION SIGNAL FOR A CIRCUIT FOR CONVERTING THIS SIGNAL INTO A COMPOSITE COLOR VIDEO SIGNAL - Google Patents

Description

Method and circuit arrangement for predistortion of a three-line sequential Color television signal for a circuit for converting this signal into a composite color video signal In order to allow a narrow-band transmission or recording of a color television signal It is known (DAS 1 256 686) to represent three different color components Color signals in a so-called sequence of three lines one after the other (tri-part sequential) to transmit or record and for playback by means of two line delay lines and to repeat three line-frequency switches each in their dead times. All three color signals are then always available and can be through matrix circuits converted into the desired signals, e.g. a composite signal.

Here it is also known (DAS 1 261 876), the trizeline sequential To carry out transmission only for the low frequencies of around 4 to 0.5 MHz and a luminance signal containing the high frequencies of about 4.5 to 2 MHz to be transmitted or recorded in each line.

The general objective is to create a simple circuit for obtaining it of a FBASS signal from the three-line sequential signal to create the good one Image reproduction causes.

It is already known (1DAS 1 936 594) in a circuit for conversion of a three-line sequential color television signal into a simultaneous, a luminance signal color television signal containing line delay lines and line-frequency switch each repeats a color signal in its dead times the luminance signal by adding the direct, the by one line and of the sequential signal delayed by two lines. It is preferred the said luminance * density signal from equal proportions of the three sequential color signals R, G, B composed.

This luminance signal is also used to form the color difference R-Y and B-Y used. Because of the special feature, R, G, B are composed of equal parts Luminance signal result in simplifications in the reproduction circuit as well Improvements in image reproduction, especially when it is horizontal or inclined Edge.

It has already been suggested to be an additional improvement to achieve the color fidelity of the reproduced image and one of the proposed Circuit to eliminate any deviations in color that still occur, the luminance signal component Y of the color difference signals R-Y, B-Y in such a different amplitude ratio than to assemble the luminance signal YM from the three sequential color signals, that in the reproduction circuit during matrixing there is a true-to-color image reproduction causing color difference signals result.

The object of the present invention is to use such a circuit to bring about the generation of a composite color video signal, also with regard to its Compatibility in terms of star white reproduction with correct gradation corresponds to the standardized PAL signal and also generates a color image that corresponds to the the additional message avoids color saturation errors that still occur.

The invention consists in that the tri-line sequential color television signal an additional signal Z, which contains the color signals R, G, B with such an amplitude, that when the sequential color signals contained in the additional signal are added a luminance signal YM results, which is equal to the luminance Z signal Y of the corresponding Black and white television signal is added at least in proportions.

The invention is based first of all on the knowledge that the luminance signal YH not the correct form = = 0.59 G + 0.3R + 0.11 B (1) but the form YM = 0.33 (G + R + B) (2), which is used for improving the image reproduction in the horizontal area Edging, according to the main application, is required.

The simultaneous fulfillment of both demands seems because of the contradicting one Statement of equations (1) and (2) is not possible.

An essential inventive step is the realization that it to achieve the effect brought about by the circuit according to the main application is not required, for example in a system with the recovery of the composite color video signal from the sequential color signals (R, G, B) to transmit the original color signals. Rather, they are to use sequential substitute color signals G *, R *, B * gu, which are derived from the original sequential color signals are composed and the equation (2) in the form YM = = 0.33 (G * + R * + B *) (2a), the proportions contained therein of the original sequential color signals G, R, B must satisfy equation (1).

It follows from this for an additional signal Z that all sequential color signals should be added evenly in the event of complete alignment the form (1): Z = 0.26 G - 0.03 R -0.22 B (3) with G * = G + Z (4a) R * = R + Z (4b) = B + Z (4c) results from equation (2a) for the luminance signal after averaging and demodulation of the sequential color signals transmitted at the color carrier frequency: Y @ M = 0.33 (G + R + B + 3 Z) (2b) The following applies to the color difference signals because of the matrixing in the corresponding circuit of patent application P 19 43 672.7: Fy * = 0.59 FG * + - 0.3 FR * + 0.11 FB * (5) With the equations (4a to c) we get FY * = FG + FR + FB + FZ = FY = FZ (5a) Using the equations (4b unti c) gives stitch for the color difference signals FB * - Fy * = FB + FZ - (Fy @ FZ) (6) FB * - FY * = FH - FY (6a) The following applies accordingly: FR * - FY * = FY - FY (7) It surrendered the desired color difference signals of the standardized PAL color signal.

The procedure can accordingly be applied to a system in which, for example, instead of the sequential color signals (G, R, B), the sequential Color signals (Y, B, R) are transmitted0 An embodiment of a circuit for Implementation of the method according to the invention and its expedient developments are explained with reference to the drawing.

The figures show: FIG. 1 the principle of the tri-line sequential recording FIG. 2 shows a block diagram of a circuit for carrying out the method of FIG. 3 shows a block diagram of an expedient development of a circuit for implementation of the method, FIGS. 4 and 5 show a circuit for converting a trizeline sequential Color television signal into a composite color video signal as shown in Fig. 1 are on the same Track of a recording medium line by line alternating from 0 to 015 MEIz - the color signals X, GtS and, in the range from 0X5 to 2 MHz, a luminance signal I in each line recorded.

In Fig. 2 are at the terminals 31,32,33, which represent the three primary colors Color signals R, G, B in the range from 0 to 0.5 MHz available without gaps. With an in Direction 43 rotating switch 34 the three color signals R, G1B line by line tapped off one after the other and fed to an adder 40. The switch 34 is controlled by a synchronization stage 35, which also have identification pulses to identify the color signals. The color signals are also the Evaluation levels 36,37,38 supplied. The evaluated color signals, the standardized form the additional signal Z, are thus independent of the sequential color signal the position of the rotating switch 34 in the adder 40 added. After this in the adder 42, the identification pulses of the synchronizing stage 35 and the luminance signal YH = 0.5 to 2 MHz, which is available at terminal 30, the sequential color signal have been added, the resulting ~ signal ~ is supplied to the recording device 1.

Should the exceeding or falling below certain amplitude values of the Transmission channel for the sequential color signals should be avoided, so it is in the embodiment shown in Figo 3 of a circuit according to an advantageous Formation of the method according to the invention favorable if, for example, by a Attenuation stage 39 attenuates the original trisquential color signal by a factor of C. and the individual color signal components contained in the additional signal Z by corresponding Interpretation of the evaluation levels 36 to 38 by (1-C) are raised Attenuation of the discrete color components in the tri-sequential color signal can be caused by an increase in the difference signals in the circuit of FIG. 4 by dashed lines Amplifier elements shown or a slightly modified circuit design earth balanced again. Should a deterioration in the signal-to-noise ratio of the sequential Color signal cannot be standardized in purchase, so it is also with the help of a non-linear one Discriminator circuit 41 and three further adding stages 36a, 37a, 38a possible, according to a type of regulation when exceeding or falling below specified amitude values to weaken or completely suppress individual color components of the additional signal. The one formed by the discriminator 4t and the addition stages 36a, 37a and 38a The limiting device is designed in such a way that that the signal levels of those contained in the additional signal; n color signal components are reduced that correspond to the sequential Color signal with the same sign can be added if this is a given one Signal level exceeds and / or that the signal level of those in the additional signal The color signal components contained in the sequential color signal are reduced1 are added with the opposite sign if this is a given one Signal level falls below.

This limiting device allows a large signal-to-noise ratio of the sequential color signal at the expense of a complete correction of M after Equation (1) with a predominant blue or green component of the color image achieve the In Fig. 4 shown playback circuit processed instead of the signals R, G, B in analogously the signals R *, G *, B *.

The signal recorded on the recording device 1 as shown in FIG. 1 is converted into the signals YH and R * by means of a low pass 2 and a high pass 3, G *, B * split. YN is fed to an adder 4. The sequential signal R *, G *, B * become a color carrier generated in an oscillator 6 in a modulator 5 modulated and fed to the series circuit of two delay lines 7, 8, to which a switch 9 is connected, which is controlled by a clock 11 by the line frequency Pulses 12 in a known manner (I) AS 1 25G G86) so ge is controlled that at his three outputs constantly have the colored signals FG *, FR *, FB.

Di @ @ arbträgerfrequenten color signals from the input, center and The series connection of the delay lines 7, 8 becomes an adder stage 13 fed, the inputs of this Level are equivalent and such dimensioned that the adder 13 the signal according to equations (2a) and (2b) in color subcarrier frequency Form supplies. The result is one containing the low frequencies from 0 to 0.5 Mllz Luminance signal FYM, which is demodulated in a demodulator 14 and in the adding stage 4 combined with the luminance signal YH to form the complete luminance signal and forms part of the PAL-FBAS signal at a terminal 15. The signals R *, G *, B * (in color subcarrier frequency form) at the three inputs of the Adding stage 13 are swapped from line to line. But this has no purpose flow because the three inputs are equivalent. It can be seen that the extraction of the luminance signal YM without the use of line-frequency switches.

The modulated color carrier for the composite signal is measured as follows obtained: The signals FG *, FR *, IeB are converted into 10 by color carrier frequencies in a matrix Matrixing of color carrier frequency signals FB * -Y * = FB-Y and FR * -Y * = FR-Y (according to equations (6a) and (7a)). The luminance signal component Y in these signals is included composed of the signals G, R, B according to equation (1), as it is for a true color Playback is necessary, with a phase switch 18, which by a half-line frequency Switching voltage 19 from the clock generator 11 from line to line between +900 and -90 ° is switched, the line-frequency polarity reversal required for the PAL color carrier is used of the Fnly signal is reached. The signals that may have been amplified in stages 23 and 24 FB-Y Y and F + j (, qy) give the adder 4 the modulated color carrier.

5 shows the basic structure of the matrix 10. The signals le FG *, FR *, FB * are fed to a resistor matrix 20.

This is dimensioned so that the luminance signal component at its output 21 Y * arises in the composition according to equation (1). This is in subtraction steps 16.17 subtracted from the respective color carrier frequency color signals FB * and FR *, so that the color carrier frequency signals FB-Y and FR-Y are at the output of these stages, which are then assembled as shown in Fig. 4 to form the PAL color carrier.

Claims (6)

Claims Process for pre-distortion of a tri-line sequential color television signal, the one with a circuit containing a luminance signal YM and color difference signals FUAS color video signal is converted using line delay lines and line-frequency switch each repeats a color signal in its dead times and the luminance signal YM of the composite signal by adding the sequential Color signals is obtained from three consecutive lines and the luminance signal component Y of the color difference signals R-Y1 B-Y in such a different amplitude ratio composed of three sequential color signals as the luminance signal YM is that in the reproduction circuit in the matrixing true-color image reproduction causing color difference signals result, characterized in that the triceline sequential Farbfernsehsig nal an additional signal (Z), which the color signals (R, G, B) with such Amplitude contains that when adding the additional signal containing sequential Color signals result in a luminance signal (YM) that is equal to the luminance signal (Y) of the corresponding black and white television signal is added at least in proportions will. 2) Method according to claim 1, wherein the luminance signal through temporal determination of three sequential color signals is obtained, characterized in that that the luminance signal (YM) has the form YM = 0.59 G + 0.3 R + 0.11 B. 3) Method according to one of the preceding claims, characterized in that that the additional signal (Z) is limited in such a way that the three are the additional signal (Z) containing sequential color signals does not have a predetermined signal level exceed or fall below. 4) Method according to one of the preceding claims, characterized in that that the amplitude of the tri-line sequential color signal before adding the Additional signal (Z) reduced and the color components contained in the additional signal as well the color difference signals (R-Y, B-Y) formed in the display circuit accordingly be strengthened0 5) circuit for performing the method according to claim 1, characterized in that the tri-sequential color signal is the additional signal forming color signal components are added with an adder (40) and that Means for amplitude-wise evaluation of the additional color signals (36 to 38) are provided. 6) Circuit according to claim 5 for performing the method according to Claim 3, characterized in that a limiting device (36a, 37aX38a, ii) is provided which contains the signal level of those in the additional signal (Z) Reduced color signal components that correspond to the sequential color signal with the same sign are added when this exceeds a predetermined signal level and / or the signal level of those color signal components contained in the additional signal is reduced, which are added to the sequential color signal with opposite signs, if this falls below a specified signal level.