DD44753B1 - DECODER FOR THE COLOR CARRIER OF A COLOR REMOTE SYSTEM - Google Patents

Description

The invention is based on a modified NTSC system with switching of a modulation axis. Because of the demand for compatibility imposed on all color television systems, only the usual bandwidth of black and white transmission is available for the transmission of a complete color television signal. It is known to choose a color carrier for the transmission of the color signals, whose frequency is within the frequency band of the brightness signal. If possible, this color carrier should be located at the upper edge of the standard band in order to influence the brightness signal little. In this design, however, the upper sideband of the color carrier is trimmed by the transmission curve of the intermediate frequency amplifier, which is to steam the adjacent channel to avoid interference.

In order to achieve a useful compromise between these two opposite requirements, in particular to ensure adequate transmission of the upper sideband, it is known to transmit two color difference signals I ', Q' with different bandwidth, wherein in both color difference signals the upper sidebands

extend to the upper limit of the transmission channel and variously into the brightness band. The broadband signal I ¹ is transmitted in order to achieve greater effective bandwidth in vestigial sideband technology. The signal Q ¹ , on the other hand, transmits areas of the color diagram that are less sensitive to the eye '. It can thus be designed narrow band, so that here the application of the double-sideband technology is possible.

However, this method has the disadvantage that the trimming of the sideband of a color difference signal due to the formation of a so-called quadrature component produces crosstalk in the other color difference signal. For example, due to a poorly balanced IF amplifier in the transmission path, a truncation of the Q 'signal may occur despite the low bandwidth of the Q ¹ signal. This causes coloring errors at the color transitions in the reproduced image.

Another difficulty due to the compatibility requirement is that the transmitted color carrier becomes visible as a disturbing pattern in the image, both in the black-and-white receiver and in the color television receiver. To reduce this disturbance, it is known to set the frequency of the color carrier in a certain ratio to the line frequency or to switch the phase of the color carrier from raster to raster. However, these solutions have proven to be insufficient. In addition, the color carrier is rectified on the non-linear characteristic of the display tube, so that an additional, the gradation falsifying brightness information as a function of the color saturation arises. In color television receivers, although it is possible with increased effort to keep the color carrier by a filter in the brightness channel of the picture tube. Black-and-white receivers, which already exist and must be suitable for color television signals without modification, do not have these filters.

It is also known to modulate the color carrier in the single-sideband method in a system with rasterfrequentem phase change of the color carrier and provide in the transmission path or in the receiver a transmission curve with a Nyquistflanke for the frequency of the color carrier. The color carrier can then be further applied to the upper limit of the transmission bandwidth, so that the influence of the color carrier is reduced to the brightness signal and the compatibility is improved. However, such a single-sideband transmission has, as will be explained in more detail with reference to the figures, the disadvantage that occur in a phase-modulated color carrier Einseitenbandfehler that manifest themselves in a crosstalk between the color channels and therefore in a Farbtonverfälschung reproduced image.

There is also a color television system known (US-PS 29 kj

in which the Farbträgei * with respect to two mutually perpendicular modulation axes with two color signals quadrature modulated and the phase of a modulation axis line frequency by l80 is switched. In this system, by switching the phase of a modulation axis hue errors in the receiver from line to line affect in the opposite direction. Due to the integrating effect of the eye the right color tone is perceived.

However, this system has one more drawback. Since the lines that are consecutive in time are, because of the interlace, the spatially consecutive lines 1, 3, 5, they are not immediately adjacent. In the case of large phase errors, in which the colors deviate strongly in successive lines, the eye then sees a line structure moving in the vertical direction.

The invention has the purpose of improving the image reproduction in the receiver in a color television system of the type described last.

The invention has for its object to provide a decoder for the color carrier of the last-described system in which Einseitenbandfehler and residual sideband error in the color carrier automatically compensated and thereby occurring in the reproduced image errors are reduced.

The invention is based on a decoder for the color carrier of a color television system in which the color carrier is quadrature modulated with respect to two mutually perpendicular modulation axes with two color signals and a modulation axis is switched from line to line by l80.

The invention consists in that a modulated color carrier leading terminal is connected both via a delay line with the delay of a line duration to the first inputs of each adder and on the one hand directly and on the other hand via a l80 phase rotator to the second inputs of the adder and the output of each adder is connected to the input of each amplitude demodulator.

Another advantage achieved by the invention is that the electronic averaging of the two modulated color subcarrier each of two temporally successive lines, an electronic compensation of the resulting on the transmission path phase error takes place. This also avoids the above-described noise in the reproduced image with larger phase errors. The circuit according to the invention causes, as explained in more detail in the description, an advantageous splitting of the modulated color carrier in its two farbträgerfrequenten shares, which correspond to the two modulation axes. These two color carrier frequency components can then be demodulated separately by adding the locally generated reference carrier in order to obtain the color signals for image reproduction. _

The invention is based on the fact that the switching of the phase modulation direction of the color carrier simultaneously means a switching of the rotation direction of the sidebands and therefore alternately both sidebands are available in temporally successive lines, although in fact always only one and the same sideband is transmitted. By the invention, a signal is obtained which is modulated at each time with both sidebands. This compensates for the single sideband errors and eliminates hue errors in the rendered image that would normally occur in single sideband transmission. Another advantage is that the color channel and the delay line of the receiver can have a smaller bandwidth due to the narrowband color carrier (single-sideband modulation). In order to give the color carrier in the receiver the desired shape, a filter may be provided in the intermediate frequency path, which has a Nyquistflanke at the frequency of the color carrier.

The invention is explained in more detail below with reference to a few vector images and an embodiment in the figures. Show it

FIGS. 1, 2, 3 vector images of a color carrier transferred in a known manner,

FIG. 4 vector images for explaining the mode of operation of the invention,

Figure 5 shows the transmission curve of a single-sideband transmission filter in the transmission path, Figure 6 shows a practical embodiment of a color television receiver in which the invention is applied.

It is common to represent the two sidebands of an amplitude modulated wave as vectors rotating at the same angular velocity but in opposite directions relative to the carrier. In Fig. 1, the carrier is suppressed, however, each individual vector image must be considered as if it is about its origin of coordinates with the

Carrier frequency circulated. Fig. La shows the two sidebands + Cj and -U)., By double sideband modulation of A A

Color carrier with a signal e.g. I ', be generated with suppressed carrier. The resultant R. always falls on the

Vertical line V, since the so-called quadratic components of the sidebands, so the 90 shifted to the vertical line V components cancel. Another signal, eg Q ¹ , which is modulated on the same carrier in a second modulator in 90-phase opposition in the same suppressed carrier method, produces the sideband pair depicted in FIG. In this case, too, the resultant R "has a constant phase, but 90 has been shifted. The sum A of the two resultant R and R "(I ¹ and Q ¹ ) is shown in FIG. 1c. Since I ¹ and Q ¹ and R and R "change independently, the transmitted signal A can have an arbitrary phase angle at any time. As shown in Fig. Id, the original signal can be recovered by synchronous rectifiers, each of which evaluates only the projection of the vector A onto one of two orthogonal axes corresponding to the phase of the reinserted carrier. Since the projection of the Q ¹ component into the direction of the I 'component is zero and the projection of the I ¹ component in the Q ¹ direction is also zero, the two original signals can be restored without crosstalk as long as both transmit sidebands become. It is easy to see that phase errors occur in the resultant vector R and R _R, and thus also in the vector A transferred, when a sideband, for example + Co, is absent or weakened.

Fig. 2 shows the case with two unevenly transmitted sidebands - Cw, + Ww. The path of the resultant R _M now corresponds approximately to an ellipse and no longer a straight line. The projection of this ellipse in the phase direction + 90 gives crosstalk. If one of the sidebands is completely absent, the path of the resultant will become a circle (Figure 3) and the amplitude of the component of crosstalk will become

as large as the desired component. Although you can reduce this crosstalk with certain switching means, but not avoid.

FIG. 4 shows how the sidebands transmitted sequentially one after the other are added during transmission with line-frequency phase reputition of a carrier-frequency signal. Fig. 4a shows the transmitted during line 1 sideband with the direction of rotation - ^ _M i Fig. 4b transmitted during line 2 sideband with the direction of rotation + Cj ... If the signal of line 1 delayed to line 2 and then in phase added, the signal of Fig. 4c. As you can see, the resultant is R-. again in the vertical, because both oppositely rotating sidebands are present. Thus, it is precisely the signal of a double-sideband transmission as shown in FIG. Of course, the invention can also be extended to vestigial sideband transmission.

In Fig. 5, the transmission curve of a transmission filter for transmission with single sideband and weakened color carrier is shown. The various broadband signals I ¹ and Q ^{1 of} the known type of modulation with double-sideband technology or vestigial sideband technology are shown in dashed lines. The transmission curve D has a Nyquistflanke N, which has a reduction of 6 db at the location of the color carrier F. It can be seen that due to the single sideband method, the color carrier F can be applied close to the sound carrier T. All advantages of double-sideband modulation are retained because both sidebands are obtained at the receiver.

In Fig. 6, a receiver circuit for obtaining the farbträgerfrequenten signal with two sidebands is shown in principle. The color carrier is canceled by a terminal 4 via a delay line 5 with the delay of a line duration, the damping of the delay line 5

Amplifier 6 and a variable phase rotator 7 a linear adder 8 supplied. The adder 8 is also supplied to the modulated color carrier via a line 9 without delay. Amplifier 6 and phase rotator 7 are set so that at the adder 8, the carrier vectors with the same amplitude and the same phase, and cover the same image components of successive lines. The output signal of the adder 8 passes via a line IOan the input of a normal amplitude rectifier 11, at the output terminal 12 is a demodulated color signal. The adder 8 is also supplied from a reference carrier oscillator 15 of the restored reference carrier via a line 22. The reference carrier oscillator 15 is synchronized via a line 23 from the color synchronizing pulses obtained from the video signal and via the line 24 from the line generator 17. Pulses coming from line generator 17 via line 2k sense the color sync pulse out of the video signal. The color carrier delayed by one line duration also passes from the phase rotator 7 to a linear adder 13 ", which, on the other hand, is supplied with the color carrier from the clamp k via a l80-phase driver l4. The adder 13 is also supplied from the reference carrier oscillator 15 via a phase changeover switch l6 of the reference carrier. The phase rotation of the phase changeover switch 16 is switched line by line between + 90 and - 90 with meander pulses l8 coming from the line generator 17. The output of the adder 13 is connected via a line 19 to the input of a normal amplitude rectifier 20, at the output terminal 21, the second demodulated color signal is. It is readily apparent that in the adder stages 8 and 13 color carriers of temporally successive lines are composed. The circuit also shows that at the output of each adder stage 8 and 13 there is always only one component, namely the same component of the quadrature-modulated signal, because due to the phase changeover of the color subcarrier at terminal k , a modulation axis is arranged in chronological succession.

the following lines is switched. If the I ¹ -axis is switched line-frequency by l8o, then there is always only the signal 2 Q ¹ at the output of the adder 8 and only the signal 2 I ¹ at the output of the adder 13 because of the phase rotator 14 and the phase switch l6. Both are farbträgerfrequente signals, which now contain both sidebands. As a result, a distortion-free demodulation in the subsequent two amplitude rectifiers 11, 20 is possible.

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Claims (2)

claims 1. decoder for the color carrier of a color television system in which the color carrier with respect to two mutually perpendicular modulation axes with two color signals quadrature modulated and a modulation axis from line to line by l80 umgeschalte't, characterized in that a modulated color carrier (F) leading terminal (4t) both via a delay line (5) with the delay of a line duration to the first inputs of each adder (8,13) and on the one hand directly and on the other hand via a 180-phase rotator (ΐΛ) to the second inputs of the adder stages (8, 13) and that the output of each adder stage (8, 13) is connected to the input of each amplitude demodulator (11, 20). 2. Decoder according to claim 1, characterized in that in series with the delay line (5) an adjustable phase rotator (7) is connected. to. ^ pages drawings