DE2223558B2 - PAL COLOR IMAGE SIGNAL DECODER CIRCUIT FOR COLOR TV RECEIVER - Google Patents

Description

The invention relates to a PAL color picture signal decoder circuit of the type described in the generic term of claim 1.

In the PAL color television system, the chrominance signal becomes formed in that two color difference signals a common reference color carrier in quadrature modulation be modulated with suppressed carrier, one of the two components of the Reference color carrier is switched from line to line in their phase position. These in their phase position of Component of the insert color carrier switched line to line is assigned to the red color difference signal

net, while the carrier component with a time-constant phase position is the blue color difference signal assigned.

The resulting chrominance signal can be represented as a complex voltage. The corresponding

Pointer is denoted by F or F ' , where the designation F refers to those lines in which the modulation axis of the red color difference signal leads the modulation axis for the blue color difference signal by 90 °, while the designation P.

mark the pointer that arises during the remaining lines in which the modulation axis of the red color difference signal lags behind that of the blue color difference signal by 90 ". This can can be written mathematically in the following form:

respectively.

F = (Eg- Ey) + j (E "- F ' = (E ₈ - Ey) - j (E _R -

Here, E _B and Er mean the blue and red primary color signal and Eyd the luminance signal.
To regenerate the

When the reference color carrier is pressed in the receiver, a color sync signal is added to the overall signal emitted by the transmitter, which is also referred to below as the burst signal for short. In the PAL color television system, these color synchronizing signals change their phase position from line to line. It is thus possible in the receiver to distinguish between the different modulation states identified by the pointers Fund F '. The chrominance signal assigned to the chrominance signal F is referred to below as B ₊ .

It is phase-shifted by 135 ° with respect to the modulation axis of the blue color difference signal. The color sync signal assigned to the color signal F ', which is referred to below as B- , is around relative to the modulation axis of the blue color difference signal

ho -135 ° out of phase.

Subject of the main patent 20 64 153.6 is a color television receiver circuit in which from the such chrominance signals are output from the original chrominance signal by means of a switch operated at line frequency.

(15 can be selected in which the two chrominance signal components always have the same relative phase position and with a line duration or an odd number Multiples of the line duration delayed signal parts

can be combined to form a continuous modified chrominance signal, in which the chrominance signal components of all lines constantly have the same relative phase position with respect to their modulation axes. This means that only chrominance signals of the form F or chrominance signals of the form F 'are fed to the demodulators s,

It is necessary to coordinate the operation of the aforementioned switch, by means of which the aforementioned continuous ι ο chrominance signal is composed of undelayed and delayed signal parts, with the reference color carrier components regenerated on the receiver side in such a way that the latter correspond to the type of chrominance signal (F or F) fed to the demodulators . If, for example, the chrominance signal fed to the demodulator is composed of signal parts of the form F , the reference color subcarrier component fed to the demodulator must correspond to a modulation axis which is phase-shifted by 4-90 ° with respect to the modulation axis for the blue color difference signal. If a chrominance signal of the form F 'were to be demodulated with the same reference color subcarrier components, an incorrect result would obviously be obtained. For this reason, coordination between the work cycle of the switch and the reference color carrier components generated from the color sync signals on the receiver side is absolutely necessary.

In the PAL color television system in which the synchronous color signals transmitted at the beginning of each line ^ o are switched from line to line in their phase, a certain pulse cycle is only repeated in every fourth field. This is a consequence of the odd number of lines, the interlace method and the fact that the last burst before and the first burst after Vertical blanking gaps should have the same phase position.

When synchronizing multiple video signal generators, both the lines and the grids of the individual video signals coincide in time so that when the signals are faded or mixed, the different signal generators do not result in interference. Since the PAL color television system has a certain Pulse cycle - as mentioned - is only repeated in every fourth field (raster), it is used for synchronization therefore required to identify four consecutive grids. Solutions to this problem are in the DT-AS 11 94 446, the DT-AS 12 67 246 and the DT-PS 12 48 708 described.

In the case of the subject matter of the main patent 20 64 153.6 forming color television receiver circuit, there is a need to switch, by means of which the original received PAL color signal is switched so that the demodulators this color signal alternately is supplied directly and delayed by a predetermined period of time to control that off Dividing the original chrominance signal and its repetitions combined modified chrominance signal always the correct phase relationship with regard to <> o the reference color carrier used for demodulation having. In the DT-PS 22 02 911 is a circuit arrangement proposed that solves this problem by means of a timer stage which is controlled by the Vertical synchronization pulse is controlled with respect to (> s this has a fixed time slot, that burst signal which is the first to follow this vertical synchronization pulse in terms of time. That way will a correction signal obtained for the switch, through which the coordination described above is established will.

In the DT-OS 22 07 744 a control circuit is described that the problem of coordinating the Switching phase of the switch solves that a z. B. designed as a bistable multivibrator circuit unit a pulse is generated, the duration of which is for the period between the vertical synchronization pulse and the The first color sync signal that occurs thereafter is characterized by the fact that a control signal is generated from this pulse is derived, the amplitude of which is a measure of the pulse duration and that this amplitude in such a way it is assessed that a correction signal for the switch is generated if and only if the end of the Pulse duration is within a time range in which only color sync signals of a predetermined Phasing can occur.

The invention is based on the object of creating a further circuit variant by means of which the correction of the switching phase of the switch required in the decoder circuit according to the main patent to form the composite modified chrominance signal can be achieved without great effort.

This object is achieved by the features mentioned in the characterizing part of claim 1.

A signal is generated by means of a first circuit unit, which is used for the in the modified, d. H. composed of parts of the original chrominance signal and delayed parts of the same Chrominance signal is characterizing existing sync signals. This signal possesses during one Part of the vertical blanking interval, in which no color sync signals are sent, is essentially one constant value. The duration of this part of the vertical blanking interval depends on whether the Switch for line-frequency switching works correctly or not, different sizes. Hence can the "correct" switching phase of the switch can be clearly determined by a simple time comparison. For this purpose, the time interval between the two immediately adjacent to the vertical synchronization pulse is used Color sync pulses compared with a fixed period of time. If the time difference between the two Color sync signals is greater than this period of time is a correction signal for the via an AND element Switch generated. If, on the other hand, the time interval between the two color sync signals is smaller than that mentioned time span, this is taken as an indication that the switch is working with the correct switching phase and a correction signal is accordingly not required.

Advantageous developments of the invention are described in the subclaims.

In the following the invention will be explained in more detail with reference to the drawings.

Figs. 1A-ID show waveforms for explanation of the pulse scheme in the area of the vertical blanking gap for four successive fields of a color television signal according to the PAL system;

Fig. 2 shows the block diagram of an embodiment of the invention;

3 shows circuit details of the block circuit image according to FIG. 2;

Fig. 4 shows a vector diagram for illustrative purposes the relative phase position of the color sync signals and the chrominance signals that are generated with the help of the Schaltunf according to FIG. 2 are decoded;

Fig. 5A-5C show the timing of the color sync signals in the area of the vertical blanking interval;

Figs. 6A-6F show waveforms of the circuit according to FIG. 3 with the correct switching phase of the switch;

7A-7E show the corresponding waveforms in the event of a wrong switching phase of the switch to generate the modified chrominance signal.

The in F i g. The waveforms shown in FIG. 1 show part of the vertical blanking intervals of four successive fields of a PAL color television signal. The signals are drawn in such a way that the vertical synchronization intervals Vs for each of the partial images shown are perpendicular to one another. The last line of the first field (FIG. 1 A) and of the third field (FIG. IC) each have only half the line length. The last lines of the second and fourth fields (FIG. 1B and ID) are whole lines. The last lines of each field are followed by the preliminary runners Ep . These are followed by the vertical synchronization signal Vs , which consists of a series of square-wave pulses. The latter is followed by the posterior satellite Ep . The transmission of line synchronization pulses then begins again, with the image initially being blanked. The vertical blanking interval has a total duration of 25 line intervals. The duration of a line interval is also designated by W in the following.

A color sync signal is transmitted on the back porch of each line synchronization pulse. The only exceptions to this are the line synchronization signals that occur immediately before, during and immediately after the vertical synchronization interval. The color sync signals are indicated as arrows and denoted by B ₊ or B- according to their different phase positions.

In the PAL system, the last color sync signal of each field and the first color sync signal following the vertical sync interval are of the form B ₊ . As a result, no burst signals are transmitted during the line synchronizing pulse before the last entire line of the signal shown in FIG. 1A. Even during the following nine line intervals, ie during the subsequent time period of 9 H, no color sync signals are transmitted. This time interval is shown in FIG. 1A to 1D is indicated by vertical lines and has the same duration for all part images, but its initial position is different relative to the beginning of the synchronous synchronization Vs for all part images.

F i g. 2 shows the block diagram of a receiver with a PAL color image signal detection circuit according to FIG Invention. In the following, the circuit structure of the receiver will first be explained: It is a UHF tuner 12 and a VHP tuner 13 are provided, which are equipped with a UHF antenna 10 or with a VHF antenna 11 are connected. The output of the VHF tuner 13 is with a picture intermediate amplifier 14 connected. Its bandwidth is chosen so that it allows both the image and the audio signals to pass. A first Output of the BILD intermediate frequency amplifier 1st with connected to a tone intermediate frequency amplifier 15 which contains a demodulator for the audio signal, The output of the demodulator is fed to and from a tone frequency amplifier 16 fed to a loudspeaker.

The image intermediate frequency amplifier 14 contains a detector for modulating the image intermediate frequency signal. The demodulated video signal appears at a second output of the image intermediate amplifier 14 and is fed to a video amplifier 17 for the luminance signal V and to a bandpass amplifier 18. The output signal of the bandpass amplifier 18, which contains the color sync signal and the chrominance signal, is fed to a circuit 5, which derives a modified chrominance signal therefrom in the manner described above. The circuit S

ίο consists essentially of a switch 20 and a delay element 19. The switch 20 changes its switching phase at the line frequency. To form the modified chrominance signal become only the original chrominance signals corresponding to every second line used. These chrominance signals are under the influence of the switch 20 once directly and once around the Duration of one or an odd number of lines delayed to the output of the circuit S switched through. For this purpose, one input terminal of switch 20 is immediate and a second input terminal of the switch 20 is connected to the output of the bandpass amplifier 18 via the delay element 19. The switch 20 is of course an electronic switch.

The output connection of the switch 20 is via a phase shifter with the input of a second Bandpass amplifier 21 connected. Its output leads to a demodulator 22 for synchronous demodulation that contained in the modified chrominance signal

.10 blue and red color difference signals. The one at the exit of the demodulator 22 appearing color difference signals are fed to a matrix with an amplifier. The luminance signal is fed to another input of this matrix. The matrix suspends

.is these input signals the primary color signals En, Er and Ec; together.

The switch 20 is under the control. inflow of a Flip-flops 25, which toggles it at the end of each line interval. The flip-flop 25 is controlled by an identification circuit 26, which will be described in detail below.

The output of the circuit S is connected to a color synchronizing signal gate circuit 27, which will hereinafter also be referred to as the burst gate for short

■ is This burs (gate, to which the modified color arti gnal is supplied, leaves only the color sync signalc happen. The output of the burst gate 27 wire a generator 42 is supplied, which is made up of a quartz tuned to the frequency of the reference color table;

so 28 and an amplifier 29 consists. The generator 4; generates a continuous periodic signal of de Frequency of the reference color carrier. Its output signal controls an oscillator 30, which is used for synchronous demo dulation required reference carrier vibration c

ss with the correct phase position. Another The output of the amplifier 29 is connected to a detector 3 for automatic control. Desse The output is connected to the first band volume amplifier 181. The output signal of the detector 31 increases

(to automatic color control is also a Color lock 32 supplied. When receiving black and white broadcasts, this generates a signal through which de second bandpass amplifier 21 and thus the overall low-frequency color part is blocked. The dcmodi fts Horte output signal of the intermediate image frequency The stronger 14 is also fed to a circuit 33 for separating the synchronizing signals, this delivers the vertical synchronization signals Vs to a

Frame rate oscillator 34 and to the identification circuit 26. The output of the frame rate oscillator 34 is connected to an output stage 35. The circuit 33 for separating the synchronizing signals is also included a line oscillator 36 connected, the output * signal of a line output stage 37 and a high voltage rectifier 38 is fed. The output signals of the image output stage 35 and the line output stage 37 are with the corresponding deflection coils of a cathode ray picture tube 39 connected. This cathode ray ι ο picture tube 39 is also used by the high-voltage rectifier 38 generated high voltage and the primary color signals generated by the matrix and amplifier circuit 23 are supplied.

The output signal of the line output stage 37 is also used for blanking the color sync signals Burst gate 27 supplied. It is also used to control the flip-flop 25.

The power supply and rectifier part required for power supply is denoted by 40.

F i g. 3 shows the color code of the receiver with more detailed circuit details. This color part contains the mentioned identification circuit 26. The relative phase position between the signals to be identified is shown in FIG. The blue color difference signal:> (En- γ) is modulated on a reference color carrier signal of always the same phase position during all lines. The red color difference signal is modulated onto a reference color carrier signal, the phase position of which is switched from line to line by 180 ". In those w lines in which the composite chrominance signal is in the form

F- (E _n -IWhJ

IW)

is present, i.e. is in the first quadrant, the assigned color sync signal δ _(is in the / wide quadrant and is phase-shifted by 45 ° with respect to the modulation axis of the red color difference signal. During the remaining lines, the modulation axis of the red color difference signal is inverted and fast .i <> after the modulation axis for the blue color difference signal by 90 ". The corresponding composite chrominance signal

lies in the fourth quadrant. That these lines assigned burst signal H is on the third Quuilnmlcti and the phase is advanced for the modulation axis of the red color difference signal by 45 degrees yet, the color burst ß "and therefore B differ in their y> phase by 90 °,

The in F i g. 3 illustrated switch 20 IiIOt exclusively either the chrominance signals / 'or chrominance signals Passicrcn, but not alternately both.

The Bczugsfarblragcrsigna- generated in the receiver v> Ic ₁ needed to Synchrondcmodulation of Farbtrttgcrs, suitable for Dcmodulicrung red or blue Farbdiffcrcnzsignale l'hasenlagcn must have. The sound state of the switch 20, in which it only transmits chrominance signals of the form F t ") to the domodulators 22 H and 22 0, is referred to below as the" correct "switching state. The opposite sound condition is called a "false" switching country.

The sounding shown in Flg.3 includes the M bandpass amplifier 18, the delay element 19 and the switch 20, which, as in the circuit according to FIG. 2 are connected to each other, the circuit also includes the flip-flop 25 for controlling the switch 20, the burst gate 27, which is connected to the output of the switch 20, and the generator 42 for generating a continuous periodic signal that the crystal 28 (FIG. 2) with a comparatively low quality and which is triggered by the color sync signals supplied by the burst gate 27. The circuit also contains the amplifier 29. The output signal of the generator 42 controls the oscillator 30. Its output signal is fed to two phase shifters 43 and 44 connected to one another in a cascade connection. The output signal of the phase shifter 43 has the correct phase position for the demodulator 22 /? for demodulating the red color difference signal.

The output signal of the phase shifter 44 is shifted by 90 ° and is the Demodulator 22ß is supplied for demodulating the blue color difference signal.

The oscillator 30 is also connected to the identification circuit 26, which has an envelope curve detector 46 the output signal of which is fed to a tuned amplifier 47. This amp is on matched the line frequency and generates a more or less sinusoidal signal, the frequency of which is the Line frequency. Its output is connected to an amplitude limiter 48. The output signal this amplitude limiter 48 is fed to a clamping circuit 49 which has a detector 50 is connected.

The output signal of the detector 50 is fed to the base of a transistor 51. This supplies control signals to the two circuits connected to its collector. One of these circuits has a Differential gate 52, which is connected to the input of a transistor 53 serving as a trigger. the another circuit includes a transistor 54 which acts as an impedance converter.

The transistor 53 supplies, via a diode 55, control signals for a monoslnbilcn multivibrator, the output of which is connected to the base of a transistor amplifier 57. The collector of this transistor amplifier 57 is connected to the power supply source 58 via the emitter-collector circuit of the transistor 54. The output of the amplifier 57 is capacitively coupled to a transistor 59. Its output is connected to the flip-flop 25 via a transistor 60 of a complementary type. In the following, the mode of operation of the circuit is shown in FIG. 3, reference being made to the signal thirsts shown in FIGS. 5A to 5C, 6A to 6F and 7A to 7E.

5A shows in a symbolic representation the color sync signals B ₄ and B immediately before and after the Vcriknlsynchronlsierungslntervall. The line-by-line change between δ, and ß_, which characterizes the PAL color television system, can be seen. No color sync signals are transmitted during a time interval of IO H (ie the tOfachcn cell duration), FI g. SB shows the color sync signals appearing at the output of switch 20. Gs are color sync signals exclusively of the form Bt , which are alternately contained in the original color art symbols or their delayed repetitions. The color sync signals fl contained in the original chrominance signal are shown by solid arrows, their position agrees with that of the color sync signals 0, shown in Fig. 5A. the

709 B31 / 4B1

delayed replicas are represented by dashed arrows and given the reference character B ₊ ' . They each follow by the time span 1 H behind the color sync signals B ₊ . The time interval between the last (delayed) color sync signal ß + 'in one field and the first color sync signal O ₊ in the next field is only 9 H.

The burst gate 27 selects the color sync signals from the continuously modified signal appearing at the output of the switch 20. Let it be assumed that this modified signal only contains color sync signals of the type B ₊ and B ₊ ' . These color synchronizing signals, which are shown in FIG. 6A, are fed to the generator 42, which uses them to generate the i _S continuous periodic signal shown in FIG. 6B. This signal is demodulated in the detector 46 such that only the envelope occurs at the output of the detector.

The envelope signal is fed to the amplifier 47 which is tuned to the line frequency and at the output of which an essentially sinusoidal signal with a line frequency appears. This essentially sinusoidal signal is not generated during a period of 9 H between two fields.

The aforementioned sinusoidal signal is clipped in the 2 <amplitude limiter 48 and then converted in the clamping circuit 49 into a square-wave signal 61 (FIG. 6C). The pulses which it contains and which occur at a line frequency are integrated in the detector 50. The output signal 62 appears at the output of the detector (FIG. 6D). This signal 62 is a flattened pulse which has a first value during a time interval of approximately 9 H and a second value which deviates therefrom during the rest of the time period of the partial image. When this signal 62 is applied to the base js of a transistor 51, it blocks this during an interval of approximately 9 H. During the remainder of the period of the Tcilbildcs, the transistor 51 is in its conductive state. The square-wave signal 63 shown in FIG. 6E arises at its collector.

This square-wave signal 63 is differentiated in the differentiating element 52. The output signal of the differentiating element 52 corresponding to the leading edge controls the monostable multivibrator 56. The time con _S stalled this monostabilcn multivibrator 56 is dimensioned so that at its output the in IMg. b F illustrated rectangular signal 64 is generated. This rectangular signal 64 begins at the same point in time as the signal 63, but lasts longer than this. If the duration of the reverse signal 63 is, for example, 9 H , the reverse signal 64 has a duration of 10 H. For the reasons explained below, the duration of the reverse signal 64 must not exceed the value 11 H , i. h "it must not last more than 2/7 longer than the right-hand signal 63.

The square wave signal 63 is also fed to transistor 54 and trains it to be conductive Condition. The Kollokiorsirom of the transistor 54 flows to the transistor 57. At the same time, the rectangle lies in the signal 64 un of the base of the transistor 57 un and controls this in its conductive state, the output signal of transistor 57 controls the normally off transistor 59. However, transistor 57 fulls thereby In its conducting state is controlled, you »the (. < Square pulses 63 and 64 are applied simultaneously to its collector and un its base, respectively the collector potential remains unchanged at a low level. As a result, there is no positive voltage to the base of the transistor 59, which is sufficient to control this in its conductive state. As long as the Transistor 59 is non-conductive, transistor 60 remains non-conductive, so that no correction signal to the Flip-flop 25 is transmitted, through which this is switched to its other switching phase.

If, however, the Schaller 20 is initially in its "wrong" switching phase, ie in such a switching state that, when it is switched at line frequency, it receives the color sync signals B-. and BJ switches through, its switching status must be corrected. From Fig. 5A it can be seen that the last color sync signal B .. occurring before the vertical blanking interval occurs by the time interval 1 // earlier than the last color sync signal S ₊ . The first color sync signal B- of the next field, however, is later than the first color sync signal O ₊ by the time period I H. Since every second line of the modified chrominance signal is formed from a delayed repetition of the previous (or an odd number of lines earlier) line signal, there is a color sync signal BJ of a field contained in a delayed line signal and the first color sync signal ß_ of the next following field time interval of 11 H. This time interval is the same for all partial images (height) and is thus long by 2 H undß _f than the corresponding interval for the color burst signals ß + '.

If the switch 20 is initially in the "wrong" switching state, the circuit according to FIG. 3 generates a signal 62 'which has the duration shown in FIG. 7B. This signal 62 'affects the transistor 51. This then generates a signal 63' (Fi g. 7C) which has the duration of 11 hours. The leading edge of the signal 63 'triggers the monostable multivibrator 56, which thereupon generates the same rectangular signal 64 as in the case described above. This rectangular signal 74 shown in FIG. 7D has a duration of 10 //. It is about the time period I / i shorter than the duration of the square-wave signal 63 '.

When both square-wave signals 63 'and 64 are fed to the collector or base of transistor 57, the latter does not change its switching state until the end of square-wave pulse 64. Then the non-conductive win. Since its collector, however, the conductive transistor 54 is connected to the supply voltage I- /. if the collector pole rises, it remains at its high level until the right pulse 63 'ends. As a result, a square pulse 65 is generated at the collector de: transistor 57. Di "Duuer this rectangular pulse 65 corresponds to the time difference of the two Rcclueckimpulsc 63 'and 6' and Con t accordingly I H.

The square pulse 65 controls the Trunsistor 59 ii its conductive state, so dull un its collector resistance and a tension subfall arises. The transistor 60 becomes conductive as a result of this voltage drop.

It feeds a correction signal to the flip-flop 25, while its duration corresponds to that of the rectangular pulse 6! is equivalent to. This correction signal will retrain you hip-hop 25 once /, tisaUilieh, so you the switching state of the Schuller 20 from this point in time in such a way that you and its output alleviate the color sync signal or, crschol non. The circuit thus generates according to FIG. 3 wledo the In F i g. 6A to W illustrated signals.

If the switch 20 is originally in the "wrong" switching state, it is activated by the Identification circuit 26 according to the invention at the beginning of the second partial image, that is, before the viewer sees it Detects errors, reversed to the correct switching state. This correction is effective after switching on the Device only required once, unless the switch 20 is due to temporary failure of the

Received signal or the supply voltage that falls back into the "wrong" switching cycle.

In the only embodiment described, the delay element 19 is present Switch 20. It can of course also be arranged on the switch, as is the case with e Embodiments of the main patent 20 64 1 case.

1 lici / ii (i IJIaIt / eichinuen

Claims (3)

Patent claims: 1. PAL color picture signal decoder circuit for color television receivers to ensure the correct switching phase for the selected chrominance signal components with a switch arrangement which switches through the temporally selected part of the received original chrominance signal components in an intermittent rhythm during those time segments in which the two chrominance signal Components have the same relative phase position with respect to their modulation axes, with a delay part for delaying at least the selected chrominance signal components by a time which is at least equal to the duration of the mentioned time segment, whereby delayed repetitions of at least the selected chrominance signal components are generated, the delay time is equal to or an odd multiple of the duration of the mentioned time periods and for demodulation only alternately the selected original chrominance signal components and their delayed reproduction fetches are exploited in such a way that a modified color image signal composed of chrominance and color sync signals is generated, according to patent 20 64 153, characterized in that from the color sync signals of the selected chrominance signals during the interval between the last of the color sync signals assigned to a field and the first color sync signal of the following field a flattened pulse signal (62, 62 ') is derived, this interval (9 H, Figure 6 E; 11H, FIG. 7C), depending on the mode of operation of the switch arrangement (20), has either a comparatively long (FIG. 7C) or a comparatively short (FIG. 6E) duration that the flattened pulse signal (62, 62 ') after conversion into a rectangular control signal (63, Fig. 6E; 63', Fig. 7D) controls a multivibrator which generates a pulse signal (64, Fig. 6F; Fig. 7D), the leading edge of which is essentially coincides with the leading edge of the pulse signal (63, 63 ') and its pulse length is shorter than the long (11 H) and longer than the short (9 H) of the possible pulse lengths of the square-wave pulse signal (63, 63'), that an AND- Member (57) is provided to which both the square-wave pulse signal (63 ') and the pulse signal (64) generated by the multivibrator circuit (56) are fed and which, if the phase position of the line-frequency switch arrangement (20) is incorrect, generates a correction pulse from the difference between the pulse signals (64, Fig. 7E) forms which r is fed to the switch arrangement (20) to change the switching phase. 2. Decoder circuit according to claim 1, characterized in that the pulse signal (62 ') with the comparatively long duration is two line intervals longer than the pulse signal (62) with the comparatively short duration and that the pulse signal (64) supplied by the multivibrator is longer than the comparatively short (FIG. 6E) but shorter than the comparatively long (FIG. 7C) pulse signal is. 3. Decoder circuit according to claim 1 or 2, characterized in that that of the multivibrator The pulse signal (64) supplied has a duration which is essentially one line interval is longer than the duration of the comparatively short pulse signal (63).