DK145959B - CONTROL CONNECTION FOR A PAL COLOR REMOTE VIEWS - Google Patents

Description

in 145959

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a control circuit for a PAL color television converter which generates a modified color information signal using alternate color information signals by means of a line delay circuit and a first line control controlled by the control circuit. of the original color information signal components and their delays in the delay circuit repeats.

In the PAL system, a composite color television signal comprises two color signal components, usually as color difference signals containing color information, which are simultaneously encoded by cross-phase amplitude modulation with suppressed carrier on a color subcarrier within the video frequency band, the phase signal of the video signal band being is turned 180 ° for each li-15 period. Ie the color television signal of the PAL system has two different types of oscillation alternating for successive line periods.

For decoding such a composite color television signal, various systems have been proposed in the past, e.g.

20 the so-called simple PAL system and the standard PAL system.

However, these common systems decode the PAL signals with poor quality of the rendered image or greatly increase the complex nature of the system.

The disclosure of Danish Patent Application No. 6612/70 discloses a new system for decoding the PAL signals in such a way that some of the limitations of the existing PAL decoding systems are avoided. The new system is theoretically also capable of receiving signals transmitted either by the PAL system or by the so-called NTSC system, although the current color subcarrier frequencies used in these two television systems make it difficult to take advantage of this latter property.

This known decoding system comprises an arrangement of switching circuits and associated delay means for receiving the incoming color information signal. This color information signal is first transmitted directly to demodulators in one line time interval, and then the same information is delayed one line time interval by the delay means again through the switching circuit to the demodulators in the next line time interval. The color information transmitted by the television station during the second line interval is not utilized by the receiver. The signal transmitted during the third line interval goes without delay to the demodulators and is repeated in delayed form during the time line of the fourth line. The result is that the color information signal, in which both modulation axes for two color signal components are held in fixed phase relationships during all the line intervals, is received and applied to the demodulators. In this case, it is necessary that the phases of the two modulation axes in the color information signal supplied to the demodulators for proper demodulation, respectively, have the same phases as the phases of the corresponding reference subcarrier signals coming from a local oscillator 20 that is phase controlled in relation to a color synchronous signal contained in the composite color television signal and used for demodulation of the two color signal components. One of the ways to achieve this is to detect the phases of the color information signal modulation axes, in other words, to detect the type of the color information signal and to control the switching circuit connected to receive the incoming color information signal so that the color information signal is transmitted with the correct type. to the demodulator, or to control the phase of the reference subcarrier signal from the local oscillator.

The color information signal transmitted in accordance with the PAL system contains a color synchronization signal which occupies two phase positions alternately offset 90 ° relative to each other for each line interval. These two synchronization phases occur alternately according to the phase of the one modulation axis which is reversed 180 ° for each line period.

In the PAL system, the color synchronization signals are phase-shifted 90 ° for two consecutive line intervals, as mentioned above, but there is an off period for the color synchronization signal covering e.g. nine line intervals, at 5 each transition between consecutive frames. The color synchronization signal off period consists of a vertical synchronization signal period covering two and a half line intervals at the beginning of each frame, and equalization pulse periods before and after it. In the color television receiver, the color synchronization signal is used to control the phase of a reference subcarrier for color demodulation. In order to avoid bad influence from the absence of the color synchronization signal during the extinguishing period, a final color synchronization signal is produced in one sub-frame immediately before the extinguishing period and a first color synchronization signal in one subpage immediately after the extinguishing period in the same phase, which results in the last and the first dye. sync signals in each frame are all in the same phase. This is commonly called a color synchronization arrangement in the PAL signal. The phase of the color synchronization signal corresponds to that of the two modulation axes in the color information signal, which is turned 180 ° for each line period. Thus, the color information signals in the line intervals in which the first and last color synchronization signals in the respective sub-frames are found are all of the same type. Furthermore, the location of the color synchronization off period is shifted relative to the beginning of each frame one after the other for a period of four frames.

Accordingly, the first and the last color synchronization signal in each 30 frames are of the same phase, but their locations are shifted periodically relative to each other for periods of four frames.

The present invention is a further development of said known arrangement and the object is to provide a control coupling which simply ensures that the reference subcarrier supplied for demodulation of the color information signals always has the correct phase in relation to to the modified color information signal.

This is achieved with the control circuit according to the invention, characterized in that it maintains the switching circuit in a first switching state at least at the end of the color synchronization off period, and upon the occurrence of the first subsequent color synchronization signal it switches into a second switching state.

Thus, the invention utilizes the fact that the color information signal during the line period in which the first color synchronization signal appears in each sub-image is always of a predetermined type, so that the demodulator is always supplied with a color information signal with the correct phase relationship to the reference signal carrier. of the 15 carrier signals is selected to coincide with the phase of the color information signal of this predetermined type.

This can e.g. This is done in that an input of the switching circuit is connected to the delay circuit and that from the output of the switching circuit alternately in each line period except for the line periods in the color synchronization switching period, each color information component is output on the inputs.

Other advantageous embodiments of the control coupling according to the invention are set forth in claims 3 and 4.

The invention will be explained in more detail below with reference to the drawing, in which fig. 1 and 2 show vector diagrams for explaining the PAL color television signal, FIG. 3 are graphs for explaining the same signal; FIG. 4 is a block diagram of an embodiment of the invention; and FIG. 5 are graphs for explaining the example of FIG. 4th

The distinctive feature of the PAL color television system lies in the phase relationship between the two color difference signals modulated on a common subcarrier to form the color information signal. This phase relationship is shown in FIG. 1. One of the color-5 information components, E -Ev, contains information about blue components in the television picture. The other,

Er-Ey, contains information related to red components.

Both of these color information components are modulated on the same carrier or, more specifically, the same sub carrier, but the modulation is performed separately and in such a way that, for a given time interval corresponding to one line nine of the color television image, the color information component ER-Ey is modulated by the carrier. modulation axis of the phase λ. In the same time interval, the second color component ψο 15 formation component E-E „on the carrier is modulated by a modulation signal.

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axis of phase Φ0 — That is why the color information component (Εη-Εν) "representing blue information in the given line interval n is shown as a horizontal arrow, and the red color information component (E-EJ in the same line interval 20 n is shown as a vertical arrow The vector sum of these two color information components gives a resultant signal F which is a complex voltage that can be determined by the expression: (EB-Ey) n + j (ER-Ey) n ·

The phase ratio of the following line n + 1 is also shown in FIG. 1. In this case, the color information component Eg-Εγ on the carrier is also modulated by the modulation axis with the phase Φ0 ~ ^, and consequently the color information component (E-E.) For the line n + 1 is shown in the same direction as the component (ΕΏ-Εν). . However, the color information component Ε0-Εν is modulated according to the carrier on the carrier with a modulation axis having a phase Φ0 ~ π (= - <t> 0) / ie. phase inversion with respect to the preceding line n, and therefore the color information component (ER-Ey) n + 1 for the line n + 1 is shown in the opposite direction of the component (ER-Ey) n · The signal 35 Fn + i can therefore be determined by the expression (Eg -ey) n + ^ - j (ER-Ey) n + 1 ·

The color information signal comprises a color synchronization signal which occupies different phases in the two signals 6 145959

Fn and Fn + 1 'DvS * SOm shown * Fig * 2' The phase of the color synchronization signal in the signal Fn is 45 ° prior to the phase φβ, which is shown as B +, and the phase of the color synchronization signal in the signal Fn + ^ is 45 ° behind the phase 5 φο ~ ir (= -φο), which is shown as B-.

FIG. 3 shows portions of successive sub-images in the PAL signal with the off periods of the color synchronization signals and adjacent parts thereof. In the PAL signal shown, one image consists of 625 line periods, and the signal 10 contains at the transition part between consecutive sub-frames an off period Ββ of the color synchronization signal at nine line intervals (9H), which consists of a period of a vertical synchronization signal Vg which at the beginning of each subpage appears in two and a half read intervals (2.5H), and of periods of prior and subsequent equalization pulses and E1, which come before and after the vertical synchronization signal Vg. The color synchronization signal off period Ββ is incrementally shifted in time in the four frames, and in the fifth part-20 image it returns to the position in the first frame. Namely, the color synchronization signal off period Bg is shifted over a period of four frames. The first color synchronization signal in each frame immediately after the off period Bg is a color synchronization signal B +, which is always 135 ° ahead of phase relative to the axis BY, as indicated by an upward arrow, and the last color synchronization signal immediately before the off period B a color synchronization signal B +, p _ which is also 135 ° ahead of phase relative to the axis BY.

Namely, the switch-off period Ββ is always followed by a line signal, hereinafter referred to as a plus-line signal, which in a horizontal switch-off period contains the color synchronization signal B + with the phase 45 ° before the axis Φ0, and in which the phase of the red color difference signal φ is φ · The plus line signal is followed by a line signal, hereinafter referred to as a minus line signal, which contains a color synchronization signal B-, whose phase is 45 ° behind the axis -φβ, and in which the line signal phase of the modulation axis of the red color difference signal is -φ.

Then the plus and minus signals follow alternately. As shown in FIG. 3, accordingly, the location of the first color synchronization signal 5 B + relative to the vertical synchronization signal Vg is shifted periodically over a period of four sub-frames. The figures in FIG. 3 indicates the line number in each image.

FIG. 4 shows an example of the converter system according to the invention. Reference numeral 1 denotes a bandpass amplifier from which the color information signal is separated from the composite color television signal. The color information signal separated by the band-pass amplifier 1 is directly applied to an input terminal 9a on a switching circuit 9 and at the same time another input terminal 9b through a delay link 10, of which the color information signal is delayed for each horizontal line period. The switching circuit 9 is switched alternately for each horizontal line period, as explained later, by switching signals from output terminals 11a and 11b on a bistable multivibrator circuit 11 which is switched over for each horizontal line period, and the output signal from the switching circuit therefore twice each of the demodulators 2 and 3 applied, namely the color information signal from only the plus line or minus line.

Furthermore, the color information signal from the band-pass amplifier 1 is applied to an opening circuit 4, from which the color synchronization signals B + and B- are alternately derived in the plus and minus line signals. The color synchronization signals B + and B- are applied to a crystal wave generator 5 to produce a carrier signal having a phase coinciding with the axis - (BY) midway between the signals B + and B-, and the thus obtained carrier signal is applied through a phase switch 7 for a local oscillator 6. therefrom deriving a reference subcarrier signal with a phase coinciding with the axis BY, i.e. ~0 ~ 2 'applied to a single demodulator 2. Furthermore, the reference sub-wave signal derived from the local oscillator 7 is applied to the second demodulator 3 through a 90 ° phase shift circuit 8. The output side of the opening circuit 4 is through a differential circuit 14 and a rectifier circuit 14. 15 is connected to base 5 of a transistor 16. Between a power supply terminal 17 and frame is a series connection of a resistor 18 and a capacitor 19. A diode 20 is connected between the collector of the transistor 16 and the connection point between the resistor 18 and the capacitor 19. and this connection point 10 is connected through a capacitor 21 to the base of a transistor 22. Furthermore, a diode 23 is connected between the collector of the transistor 22 and the one output terminal 11a of the multivibrator 11. The multivibrator 11 is supplied e.g. a horizontal line signal as a trigger signal.

15 In FIG. 5A, the color synchronization signals B + and B- which are derived from the opening circuit 4 are thus rectified by the rectifier circuit 14 and therefrom a unidirectional output signal Sjy is shown as shown in FIG. 5B. The unidirectional output is differentiated by the differential circuit 15 to produce a differentiated pulse S2 at the same time as the color synchronization signal signals B + and B-, as shown in FIG. 5C, and the differential pulse S2 is applied to the base of transistor 16. This transistor 16 has a bias so that it is conductive, although pulse S2 25 is not applied, but when pulse S2 is applied, a large current passes between its collector and emitter. , and at this point its collector potential becomes minimum, so that a signal S1 is generated on the collector, as shown in FIG. 5D. When the pulse S2 is not applied, the capacitor 19 is gradually charged to the voltage of the power supply terminal 17, but when the pulse S2 occurs, the charge stored on the capacitor is discharged through the diode 20 and the collector and emitter of the transistor 16. Accordingly, at the junction of the resistor 18 and the capacitor 19 has a signal voltage S 1, as shown in FIG. 5E, and this voltage is applied to the base of transistor 22 through capacitor 21. Since pulse S2 does not appear in the color synchronization off period Ββ, covering 9H, the signal S3 gradually decreases, and consequently the signal voltage S4 gradually increases in the color synchronization off period Β , and at time t 1, the signal voltage reaches a predetermined value at which transistor 22 becomes conductive. The collector-5 potential of transistor 22 decreases from the power supply voltage substantially to ground potential at time t ^ in the color synchronization off period Ββ. Furthermore, the signal voltage S4 is kept large enough to hold the transistor 22 conductive until the first color synchronization signal 10 in the sub-image after the color synchronization switching period occurs at time t2 such that the transistor 22 is held conductive and its collector potential in its diminished state until the end of color synchronization period B_. Accordingly, although the multivibrator 11 is in any state prior to time t1, it is maintained from time t ^ in the color synchronization off period Ββ to time tj in such a state that the potential of one output terminal 11a is substantially maintained at ground potential through diode 23 , ie in such a predetermined state that one transistor 25 is conductive and the other transistor 26 non-conductive. Accordingly, during this period, the switching circuit is kept in such a state that diode 12 is non-conductive and diode 13 is conductive.

When the first color synchronization signal B + occurs at 25 time t2 after the color synchronization off period Β β, the signal voltage S4 is lowered and blocks the transistor 22, as explained above, so that the multivibrator 11 of the water-rectifier pulse 24 is brought to such a state that one transistor 25 is non-conductive and the second transistor 30 is conductive, whereby the switching circuit 9 changes its state to conductive diode 12 and non-conductive diode 13. Accordingly, the incoming color information signal becomes in the horizontal line period where the first color synchronization signal B + occurs after color synchronization switch -35 period Ββ, directly applied to demodulators 2 and 3. Upon receipt of the next color synchronization signal B, the multivibrator 11 shifts and changes the switching circuit 9 to the state where the diode 12 is nonconductive and the diode 145959 or 13 conductive. This causes the output of the delay link 10 in the horizontal line period with the color synchronization signal B- to be applied to the demodulators 2 and 3, after which the same operations are repeated. Thus, upon receiving 5 of the plus line signal, the multivibrator 11 is brought into the state in which the transistor 26 becomes conductive and the switching circuit 9 in the state in which the diode 12 becomes conductive. By contrast, the plus line signal is directly applied to the demodulators 2 and 3. On receiving the minus line 10 signal, the multivibrator 11, on the other hand, changes to the state where the transistor 25 becomes conductive and the switching circuit 9 to the state where the diode 13 becomes conductive. Therefore, the demodulators 2 and 3 are supplied with the plus line signal from the previous horizontal line period, which is deduced from the delay stage 10. The minus line signal is replaced by the plus line signal from the previous horizontal line period, and the demodulators 2 and 3 are always supplied with the plus line signal. Accordingly, demodulators 2 and 3 are always supplied with the 20 solid phase reference subcarrier, as explained above, so that a particular signal to be demodulated is always demodulated with the predetermined subcarrier signal at any time from demodulators 2 and 3 to output predetermined demodulated color signals.

It is also possible to supply the demodulators 2 and 3 minus the line signal by reversing the operation of the switching circuit 9. In this case, however, the demodulator 3 must be supplied with a subcarrier signal of phase -φο when the color information signal from the bandpass amplifier 1 is directly applied to the demodulator 3.

With the example of the circuit according to the invention, even if the triggering of the multivibrator 11 is reversed in a partial image and brings the switching circuit 9 in the wrong switching state, so that the minus signal is applied to the demodulators 2 and 3 instead of the plus line signal, the triggering of the multivibrator 11 immediately will be controlled and the switching circuit 9 will return to its proper switching state.

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This ensures that a particular signal to be demodulated is always demodulated by a predetermined phase carrier to provide a predetermined, demodulated color signal at all times.

Although in the above example, the multivibrator 11 is driven by the horizontal line pulse, the circuit may also be driven by the horizontal sync signal or a detected output of the color sync signal synchronized with the horizontal sync signal.

Furthermore, the present invention is applicable in cases where the two color signals are I and Q signals.