DE1279727B - Multi-standard color television receivers - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

H04n

German class: 21 al - 34/31

Number: 1279 727

File number: P 12 79 727.2-31 (T 33362)

Filing date: March 7, 1967

Opening day: October 10, 1968

In the PAL color television system, a color carrier is quadrature-modulated with two color signals and one Modulation axis switched line frequency by 180 °. With a runtime signal splitting circuit the color carriers are generated by means of a delay line with the delay time of one line made simultaneously available from temporally successive lines and in an adding stage and a subtraction stage is added and subtracted. Such a receiver requires besides the delay line a line-frequency switch to switch the phase of a reference carrier used for demodulation.

With the SECAM system, two color signals are alternately frequency modulated line by line with the color subcarrier transfer. By means of a delay line for a line duration, here in each case a color signal repeats in the lines in which it is not transmitted. Again, next to the delay line a line-frequency switch is required to each time a color signal on its associated To switch channel.

In the NIR color television system, a quadrature-modulated color carrier is alternated line by line and transmit a constant phase reference carrier. They are modulated by means of a delay line Color carrier and reference carrier are each repeated in their dead times, so that in each line a modulated Color carriers and a reference carrier of constant phase necessary for demodulation are available. Here, too, a line-frequency switch is required so that the modulated color carrier is always only in the color carrier channel and the reference carrier only ever get into the reference carrier channel.

In many cases, e.g. B. in border areas between countries with different color television systems or for export purposes, multi-standard color television receivers are required to switch between operating modes for the three systems mentioned, in particular between PAL and SECAM operation, switchable are. Such multi-standard receivers are expensive and complicated because the color carriers of the individual Systems are modulated differently and demodulated in different ways in the receiver and have to be processed further.

The invention is based on the object of providing a multi-standard color television receiver for the aforementioned To create systems that can be switched to the various operating modes as easily as possible. In particular, the invention is intended to achieve that as many components as possible can be used in all operating modes.

Multi-standard color television receivers

Applicant:
Telefunken

Patentverwertungsgesellschaft mb H.,
7900 Ulm, Elisabethenstr. 3

Named as inventor:

Dr. Walter Bruch,

Dipl.-Ing. Werner Scholz, 3000 Hanover

The invention relates to a multi-standard color television receiver for systems of PAL-SECAM ^ao or NIR-type, which have a line-sequential change in the color communication and a different type of modulation of the color carrier, with a lying in the color channel, the received color carrier sequence delayed by one line period Ver ^a 5 delay line.

In such a multi-standard color television receiver the invention consists in the simultaneous use of the following, some of which are known per se Characteristics:

a) In the color carrier path behind the delay line there is a double switch, both of which Outputs in push-pull alternating line by line to one of the undelayed color carrier sequence and a terminal leading the delayed color carrier sequence can be switched.

b) The delay line and the double changeover switch are for all operating modes (PAL / SECAM / NIR) together.

c) The outputs of the double changeover switch are for switching standards to the inputs of the

Color carrier demodulators assigned to different systems can be switched over.
What is achieved by the invention is that the delay line can be used for a line duration and the line-frequency switch can be used in all operating modes and therefore only need to be present once. Switching between the operating modes is also simple, because for this purpose only the outputs of the line-frequency switch need to be switched to the inputs of the color subcarrier demodulators required for the particular operating case.

809 620/267

3 4

In PAL operation, the outputs are preferably a color carrier with a constant PAL visual condition of the switch is connected to the inputs of an adder.

and a subtracting stage for the transit time signal. In SECAM operation, the switches are 17, 18

gap circuit connected. Because with PAL and NIR in their lower position. The SECAM color operation is a quadrature-modulated color carrier, 5 carriers are now in a known manner in which the same limiters 19, 20 can be limited in these two operating modes and used in the frequency synchronous demodulators. The demodulators 21,22 demodulated. The switchover to operation for a specific color signal is automatically supplied via the switch 18 to the terminals 15,16 via an electronic signal, where the switch is then again made, which is actuated by a manipulated variable and video-frequency color signals (RY) and (BY) , which is obtained from the presence of the signal associated with this signal. It can be seen that the delay line 2 and the associated synchronization signal for the line-frequency switch 3 is obtained for both SECAM-frequency switches. The line and PAL operation can be used,
Frequente switch can also be used in all operating cases F i g. 2 shows an embodiment for switching

controlled by the same synchronization circuit 15 tion between PAL and NIR. In the illustrated will. This is particularly simple if the circuit works in all positions of the switches 17, 18 Systems use the same synchronizing signal, e.g. one for PAL operation as in Fig. 1. For NIR operation The switches 17, 18, for example, are automatic for a color sync signal with color carrier oscillations Phase switched from line to line, transmitted by evaluating the NIR synchronization signal for will. 20 the line-frequency switch, in the lower position

The invention is applied in the following on the basis of the treatment. The quadrature-modulated color explanation is then constantly available at the lower output of the switch 17, drawing in more detail on four exemplary embodiments. The F i g. 1, 3, 4 each show a PAL / carrier F, F, F ... which is fed to two synchronous demodulators SECAM receivers and FIG are connected. At the upper Ausin in Fig. 1 is a terminal 1, at which either the output of the switch 17 is constantly a reference * · PAL color carrier or the SECAM color carrier is, carrier / ₀ with constant phase, which is directly and once via a combination Via a delay stronger 62 as a reference carrier to the synchronous demodulator line 2 for a line duration to the inputs of a gate 61 and via a phase rotator 63 with a line-frequency double-pole switch 3 to the synchronous demodulator, its outputs 4.5 to inputs of a 60 is fed. The synchronous demodulators used for operating switchover double-pole 60, 61 gain as they are connected from switch 17 in an NTSC receiver. The outputs of the quadrature-modulated color carrier, the two switches 17 in the upper switch position, are each video-frequency color signals (RY) and (BY). The delay line 2 and the line extraction stage 7 are also connected to the inputs of an adder 6 and a sub-35, the outputs of which are effective at single-frequency switches 3 in both operating cases , which in turn are used by a color subcarrier oscillator 11, chrondemodulatures 8, 9 or 60, 61 and the same once directly and once via a 90 ° phase rotator 12 or 63,
dreherl2 are fed with a reference carrier f ₀ , 40 FIG. 3 shows a practical embodiment. The outputs of the synchronous demodulators 8, 9 are the circuit of FIG. 1 provided with the same reference numbers ters 18 connected. The outputs of the switch are. Four diodes serve as switch 3, and adders 17 in the lower switch position are connected to inputs stage 6 and subtractor stage 7 with two amplitude limiters 19, 20 each, the 45 standard networks together with a transformer 25 via SECAM frequency demodulators 21, 22 and with grounded Funding.

Equalizer 23, 24 to the second inputs of the Um- In PAL operation, the voltage U is connected to a silencer 18. The switch 3 is tion 26 at the output of a circuit 27, which evaluates the PAL both in PAL and SECAM operation by color sync signals, negative and controls a half-line 50 coming from a terminal 13, a diode 28 in the color carrier path through-frequency switching voltage 14 operated at a line rate. casual, so that the PAL color carrier via amplifier. The switch 18 delivers to terminals 15, 16 at 60, 29 on delay line 2. The two modes of operation, the video-frequency color signals, negative voltage U also comes via a (RY) and (BY). conductive diode 30 and a line 31 on diodes

In PAL operation, the changeover switches 55 of SECAM limiters 19, 20 and controls these 17, 18, which are coupled to one another, for example, are non-conductive diodes, so that the SECAM-FM is in the upper position. The PAL color carriers are demodulators 21, 22 no signal. The am now in the stages 6, 7 and the demodulators 8,9 output of the stages 6,7 in PAL operation arise in a known manner according to the principle of the transit time - the color subcarrier frequency signals reach the signal splitting circuit demodulated so that at the 60 PAL Demodulators 8,9 and from there via relay terminals 15,16 the demodulated video-frequency contacts a _v a ₂ to the output terminals 15,16. The color signals (RY) and (BY) are available. At the relay quiescent current contacts a _v a _{2 of} the switch 18, the upper output of the switch 17 is constantly modulated by an exciter winding A , lated PAL color carriers F, F, F ... and at the lower this winding yi is through the negative span output of the color carriers F ⁺ , F ⁺ , F ⁺ ... A voltage U not energized because this negative voltage circuit the phase of the reference carrier f _{0, which is used for demodulation because of the conductive diode 28 on the winding ^ 4} from the oscillator 11 is not necessary - does not appear. A circuit 32, which the circuit is agile because at each input of the stages 6,7 always corresponds to 27, but only the SECAM identifier

5 6

evaluates tion signal, delivers on a line 33 when (PAL) and a frequency demodulator (SECAM) absence of the SECAM signal, ie is also switchable. This circuit consists of a negative voltage in PAL operation, which blocks a transformer 42 with a primary winding 43, a diode 34, so that the PAL color carrier only passes through the diode 28 with a center tap. The circuit 27 supplies voltage 44, two mutually detuned resonances and also a synchronization signal for a circling 45, 46, two diodes 47, 48, two charge switch multivibrators 35, the half-line frequency capacitors 49, 50 and two resistors 51, 52. Switching voltage 14 for the line-frequency switching If the switch a _s or a _{s is located} in the darter 3 supplies. The circuit 27 also supplies the set position, so the circuit works as a reference carrier / ₀ , the demodulators 8,9 as in io synchronous demodulator. The reference carrier will be the FIG. 1 feeds. Primary winding 43 and the Trä-B to be demodulated in SECAM mode, so if no PAL signal is received at the junction of the capacitors, a positive 49 and 50 is supplied to line 26. The center tap of the secondary Spanmmg U, which blocks the diode 28, and on the winding 44 is grounded, and thus the AC line 33 is a positive voltage that controls the diode 34 15 voltages at the two outputs of the secondary. The SECAM color carrier is winding 44 in the same opposite direction. The two now to the amplifier stage 29. The switchable diodes 28,34 opposite to the center frequency serve to control the color carrier in PAL-tuned circles 45, 46 now like an operation via the saturation adjuster 59 and the trap circuit tuned to the center frequency. Color sync signal blanking stage 60 and at 20 Therefore, the two discriminator circuits do not interfere with the circuit operated as SECAM operation via the HF deemphasis stage 61 synchronous demodulator,
to be fed to level 29. The voltage U at the If the switches a ₅ and a _{s are} thrown, line 26 now works, since it is positive, no longer the circuit as a ratio rectifier with two via the diode 30 on the line 31, so that the detuned circuits . The FM anodes of the diodes of the limiters 19, 20 to be demodulated from a carrier are fed to the primary winding 43. The circuit 36 is now connected to another positive voltage - normally used for limiting purposes - which controls these diodes to be permeable. The charging capacitor is omitted because the carriers now act as SECAM limiters. The SECAM amplitude with SECAM in front of the FM demodulator color carrier now arrives via these limiters 19, 20 to one of the mean carrier amplitude independent of the SECAM demodulators 21, 22 and is limited to 30 dependent amplitude value,
demodulated there. The demodulated color signals switching between PAL and SECAM operation pass via equalizer circuits 23,24 via the relay Λ, whose contacts ^ relocated relay contacts a _v a _{2 have} dropped to the terminals up to a ₅ in PAL operation, ie in the 15.16. The exciter winding .4 will be in the positive position shown, and with SECAM-tive voltage on the line 26 excited so that the 35 operations are switched. The control voltage Up for contacts a _x and a ₂ in SECAM operation diverted the field winding A can be for an automatic. In the case of SECAM switching, the circuit 32 also supplies a control signal for the switching multivi- dem SECAM identification signal from the PAL color sync signal or operation 40 a negative voltage, which controls the strobe pulses 37 via a line 31, which in turn blocks the color sync signal diodes of the limiters 19, 20 so that they evaluate from the PAL color subcarrier The color carrier via a line 41. The voltage also controls the three diodes of the circuit 32 is permeable by vertical synchronizing switch 70, so that the reference carrier / ₀ pulses 38 controlled, which from the signal during 45 from the color carrier oscillator 11 in each case on the primary of the vertical blanking time Evaluate occurring SECAM identification winding 43 of the transmitter 42 in the demodulation signal Multivibrator 35 is supplied to circuits 53, 54 which, through the contacts a _s and α _Ά , which are also in rest for synchronization via an open position, supply line-frequency pulses 40 as synthesis 39. The chrondemodulator are connected. The connection circuit 32 is also the color video signal, 50 points of the capacitors 49.50 are the slower. B. supplied from the video output stages so that the subtraction stage 7 is fed from frequency color signals from the adder 6 and this the identification signal is evaluated. The reference carrier can. If neither a SECAM nor a PAL is received by the demodulator 53 via an inductance 55, the diodes 34, 38 are connected and the demodulator 54 is blocked via a capacitor. So that the circuit 32 is still supplied to 55 56 at any time. These two circuit elements can determine whether a SECAM signal is received working together with the base voltage divider, in this case the color channel is opened by each level of the transistors 57, 58 once a phase vertical blanking pulse via the diode 34, lag of 45 ° and once a Phase lead, if necessary, when receiving a SECAM of 45 °, so that overall the required phase signal is produced by the identification signals sent to the gates 53, 54 during the vertical blanking 60 shift of 90 ° between the demodule pulses,
Complete opening of the SECAM channel required. In SECAM operation, a positive DC voltage can be generated on line 26 because of the positive DC voltage on line 33 of the relay contact a _{x then folded over.} Voltage that the diodes of the limiters 19, 20 F i g. 4 shows a circuit in which the demodulator 65 controls so that the limiters transmit the color lators for PAL and demodulators for SECAM carriers to the demodulators 53, 54. The same circuit arrangement 53, 54 used diodes of the switch 70 are then impermeable, which is controlled between a synchronous demodulator, so that the reference carrier from the color carrier

oscillator 11 is ineffective. The relay contacts a ₅ and a _% are switched over, so that the demodulators 53, 54 now act as FM demodulators. The contacts a ₂ and a _t, which are also folded over, switch on the SECAM equalizers 23, 24.

The manipulated variable for switching between the two operating states can also be taken from the circuit to automatically block the color channel. The line-frequency switch 3 can be used for PAL and SECAM operation can be controlled by the same synchronizing circuit as in FIG. 3 shown. For example, in both operating cases, the synchronization circuit can be received by the same Identification signal, e.g. B. by a received color sync signal with from line to line in the Phase-switched color carrier oscillations can be controlled, albeit one with SECAM Color burst is sent. The automatic gain control of the color channel in the way of the modulated color subcarrier or in the way of the video so frequency color signals can be used both with SECAM as also be effective in PAL operation. The resistor 59 shown in FIG. 3 and 4 to reduce the amplitude of the PAL carrier is effective in PAL operation, can also be achieved by means of appropriate damping resistors in the Way of replacing the PAL or SECAM demodulators.

Claims (18)

Patent claims: 1. Multi-standard color television receiver for systems of the PAL-SECAM or NIR type, the one line-sequential switching for color transmission and a different type of modulation of the color carrier have, with one lying in the color channel, the received color carrier sequence Delay line delaying one line duration, characterized by the simultaneous use of the following in part for well-known features: a) In the color carrier path behind the delay line (2) there is a double changeover switch (3), the two outputs (4, 5) of which alternate in push-pull to one of the undelayed color carrier sequence (F, F ⁺ , F) and one the delayed color carrier sequence (F ⁺⁾ , F, F ⁺ ) leading terminal can be switched. b) The delay line (2) and the double changeover switch (3) are for all operating modes (PAL / SECAM / NIR) together. c) The outputs of the double switch (3) are for switching standards to the inputs of the different systems assigned color subcarrier demodulators (8 ^ 9; 21, 22) switchable. 2. Color television receiver according to claim 1, characterized in that in PAL reception the two outputs of the double switch (3) to two inputs of an adder (6) and a subtraction stage (7) of a transit time signal splitting circuit are connected. 3. Color television receiver according to claim 1, characterized in that in NIR operation the output (5) of the double switch which supplies the quadrature-modulated color carrier in each line (3) to the first inputs and to the one that supplies the reference carrier (/ “) of constant phase in each line Output (4) of the double changeover switch (3) with a phase difference of 90 ° to the second inputs of two synchronous demodulators (60, 61) is connected (Fig. 2). 4. Color television receiver according to claim 3, characterized in that in PAL and NIR operation the same synchronous demodulators are used. 5. Color television receiver according to claim 1, characterized in that the switchover to operation for a certain signal (PAL, SECAM) takes place automatically by an electronic switch (17,18) which is actuated by a manipulated variable derived from the presence of the to this. Synchronizing signal belonging to the signal for the line-frequency double switch (3) is obtained, 6. Color television receiver according to claim 5, characterized in that the manipulated variable consists of the circuit for the automatic blocking of the color channel is derived. 7. Color television receiver according to claim 5, characterized in that when switching between SECAM operation and PAL or NIR operation the manipulated variable (t /) on diodes from before the SECAM demodulators (21, 22) lying limiters (19, 20) acts so that the limiters are impermeable in PAL or NIR operation and permeable in SECAM operation (Fig. 3, 4). 8. Color television receiver according to claim 1, characterized in that the line frequency Double changeover switch (3) in the different operating modes by the same synchronization circuit (35) is controlled (Fig. 3). 9. color television receiver according to claim 8, characterized in that at different Operating modes the synchronization circuit controlled by the same received synchronization signal is. 10. Color television receiver according to claim 1, characterized in that to achieve a when switching standards, the amplitude of the color signals remains the same, the automatic gain control of the color channel is effective in all operating modes. 11. Color television receiver according to claim 1, characterized in that one when switching standards actuated further switch (18) is provided, each of the outputs of those Color carrier demodulators (8.9; 21.22; 60.61) whose inputs are connected to the outputs of the Double switch (3) are connected to the inputs of a matrix or of color video amplifier stages turns on. 12. Color television receiver according to claim 11, characterized in that when switching standards so dimensioned voltage divider (59) can be switched on in the path of the color carrier or in the path of the demodulators that the Color video signals at the input of the matrix or • the amplifier stages in the various operating modes always have the amplitude required for correct control of the display tube. 13. Color television receiver according to claim 1, characterized in that the shutdown of the PAL operation is carried out by switching off the reference carrier required for the PAL demodulators (FIG. 4). 14. Color television receiver according to claim 2, characterized in that the same as a PAL demodulator for the output voltage of the adding stage (6) or the subtracting stage (7) and as a SECAM demodulator for the output voltage of the line-frequency double switch (3), switchable between the two operating states Demodulation circuit (53, 54) is used (Fig. 4). 15. A color television receiver according to claim 14, characterized in that the demodulation circuit (53, 54) is connected in SECAM mode as an FM demodulator and in PAL mode as a synchronous demodulator to which a reference carrier is fed (FIG. 4). 16. Color television receiver according to claim 15, characterized in that the demodulation circuit in SECAM operation as a ratio rectifier with two via the secondary winding (44) of a transformer (42) fed with the modulated ao carrier, opposite to the center frequency detuned resonance circuits (45, 46) is connected and the base points of the capacitors (49, 50) located behind the rectifier elements (47, 48) are grounded, and that in PAL operation a center tap of the secondary winding (44) is grounded, the connected base points of the capacitors, which are separated from ground (49, 50) the amplitude-modulated carrier-frequency PAL signal and the transmitter (42) of the reference carrier is supplied (Fig. 4). 17. A color television receiver according to claim 16, characterized in that a switch (O ₃ , a ₅ ) is provided which is actuated during the operating changeover (SECAM / PAL) and which in SECAM operation the base points of the capacitors (49, 50) and in PAL operation puts the center tap on earth (Fig. 4). 18. Color television receiver according to claim 16, characterized in that in both operating modes the series connection of the two resonance circuits (45, 46) is parallel to the secondary winding (44) and its connection point is grounded (Fig. 4). Considered publications: German Auslegeschrift No. 1173 934; Reprint of the "Telefunken-Zeitung", "Selected Papers II", July 1966, p. 12; Electronics World, December 1966, p. 72; "EBV Review Part A - Technical", No. 93,
October 1965, p. 200. For this purpose 2 sheets of drawings 809 620/267 9.68 © Bundesdruckerei Berlin