DE1005119B - Arrangement for switching the deflection generators of a multi-standard television receiver - Google Patents

Description

GERMAN

The invention relates to an arrangement for switching the deflection generators of multi-standard television receivers.

Circuit arrangements are already known which make it possible to use the same television receiver Receive broadcasts that have different standards. With these known multi-standard receivers the receiver is switched to a special channel by manually inserting a tuning revolver or the like into the one Position must be brought in which the circuits closed for the desired standard will.

In the course of the development of Western European television technology, stations now frequently change TV standard, e.g. B. to take over special programs from other stations, which one of the have their own different norm. Since the transmitting station and thus the receiving channel are the same remain, the setting of the tuning turret must also remain the same, and it must in addition special means can be provided in order to adapt the receiver to the respectively changed standard for the same channel. It is therefore desirable to provide the recipient with a single selection rule.

The invention provides an arrangement by means of which the frequency of the Line or raster oscillator of a television receiver automatically adapts to these changes Line or screen frequencies can be adjusted with the same channel set in each case.

There are arrangements are known whose circuits are matched so that they are on two or can vibrate more frequencies. The deflection generator is automatically generated directly by the Synchronization pulses switched. However, these systems are very unstable because of the synchronization pulses superimposed interference or scattering, the switching times are often changed and cause a change in frequency. Consequently there is often considerable distortion in the reproduced image. According to other acquaintances Filters can be used that have a high attenuation for the fundamental frequency of the filter arrangements the synchronization pulses corresponding to a deflection frequency and low attenuation for the Base frequency of the synchronization pulses corresponding to the other deflection frequency. However, since the pulse duration, compared to the pulse spacing, is very short, the waveform of the pulses is highly asymmetrical, and the level of the fundamental frequency of the synchronizing pulses has with respect to the harmonics no longer sufficient height, so that with such an arrangement at the exit of sharp Arrangement for switching

the deflection generators
of a multi-standard television receiver

Applicant:

International Standard Electric
Corporation, New York, NY (V. St. A.)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Claimed priority:
Netherlands 5 May 1954

Lucien A. B. Cabes and Marcel van den Branden,

Antwerp (Belgium),
have been named as inventors

Considerable gain is required for matched filters.

In another arrangement, no actual deflection oscillator is provided, but one locally generated deflection voltage with a sawtooth curve automatically through each individual synchronization pulse triggered. In such a system, the image width is a function of the sampling frequency, since the duration of a sawtooth is a function of the distance between the synchronization pulses is. In addition, the line deflection can be interrupted by glitches that cause premature Can cause triggering of the deflection voltage curve. The system therefore sets for proper Working the absence of glitches, d. H.

practically with television receivers never existing ideal conditions.

The invention now relates to an arrangement for switching over the deflection generators of a multi-standard television receiver For receiving transmitters that use different synchronization frequencies with the same carrier wave. It is characterized in that the synchronizing frequencies differentiating discriminators Control arrangements that feed the deflection generator frequencies automatically in accordance bring with the respective norm of the received shipment.

According to the invention, these discriminator circuits have a monostable multivibrator that

609 866/160

is switched electronically by the received synchronization pulses and its output to a High-pass filter is arranged to screen out the direct current components of the pulses. A pulse width measuring or Pulse width discriminator provides a DC voltage potential that a function of the signal-to-space ratio. Dependent on the frequency of the deflection generator automatically depends on the size of this direct voltage potential switched.

In a further development of the inventive concept, the high-pass filter consists of a series capacitor and a cross-resistance network. According to a further development of the invention, there is Pulse width discriminator from a voltage doubler, which two with a common and on has a fixed potential applied terminal provided capacitors, which have oppositely polarized Rectifiers are charged and their free ends are connected to a high resistance potentiometer are connected so that the potential at the tap of the potentiometer is a function of the character-distance ratio is.

The invention is explained in more detail with reference to the drawing, which shows an exemplary embodiment:

According to this exemplary embodiment, a monostable multivibrator MMV, a high-pass filter HPF, a pulse width measuring arrangement or a pulse width discriminator PWO and a switching arrangement CM are connected in cascade.

Since the television sync pulse duration is only short compared to the pulse spacing, the signal to spacing ratio of the sync pulses, which is already a function of the pulse repetition rate, i.e. the deflection frequency, is very small compared to the unit, and is not suitable for high-sensitivity frequency discriminators. The monostable multivibrator is dimensioned in such a way that the signal-to-distance ratio is charged in a synchronizing-speaking manner via two oppositely polarized rectifiers D ₁ , D _2. The positive pulses charge the capacitor C ₁ via the conductive rectifier D ₁ , while the rectifier D _{2 is} blocked for this. The negative charging takes place via the rectifier D ₂ , which is permeable for this purpose, while

C ₂ a very high one

pulses is increased to a value given by the time constant R ₀ , C _{0 of} the common capacitance. The high-pass filter HPF filters out the direct current component of the waveform at the output of the monostable multivibrator MMV . This results in a new waveform in which the pulse areas above the zero potential level are equal to the pulse areas below the zero potential level, so that the peak voltages of the new pulses are a function of their duration. The pulse width discriminator rend the rectifier D _{1 is} blocked. The potential at terminal A is therefore always ίο positive with respect to the common potential point of the two capacitors, while at terminal B there is always a negative potential with respect to the common point.

Since the capacitors C ₁ and have a time constant for the discharge, they charge up to the peak voltage of the positive and negative pulses at the input of the pulse width discriminator. The potentials A and B thus represent (if the point common to the capacitors C ₁ and C _{2 is connected} to earth) the peak voltages of the positive and negative pulses, which are a function of the signal-to-spacing ratio of those pulses, which in turn are a function of the Frequency of the synchronization pulses are. At the tap of the potentiometer P there is therefore a direct voltage which is also a function of the signal-to-distance ratio of the pulses and therefore a function of the frequency of the synchronizing pulses.

It can thus be seen that practically any value can be selected for the time constant RC of the high-pass filter HPF , with the exception of very small values, for which this circuit acts as a differentiating circuit that delivers positive and negative pulses, regardless of their repetition frequency. However, it can be shown that for a certain change in the synchronizing pulse frequency, the greatest change in the direct current potential at the potentiometer tap P can be achieved for the greatest possible value of the time constant RC (infinite), for which the output of the circuit HPF practically delivers a wave of rectangular shape.

It can also be shown that the mentioned maximum change in the direct current potential at the potentiometer tap t is proportional to the period P during which the monostable multivibrator MMV is unstable, ie proportional to the time constants R ₀ , C _{0 of} the monostable multivibrator MMV. In principle, this time constant R ₀ , C _{0 should be} as large as possible, but in practice it is limited by the tolerance of the components R ₀ , C ₀ and, above all, the

30th

35

45

PWD measures the voltage peaks, which are a function 50 together with the time constants of the leakage and switching capacitances

represent the pulse width, and accordingly provides at the tap t of the potentiometer P an output voltage which is a function of the symbol-to-space ratio of the input pulses and therefore the frequency of the synchronization pulses.

The switching arrangement CM automatically changes the frequency of the deflection oscillator in accordance with the output voltage of the pulse width discriminator PfFD, so that the frequency of the deflection oscillator is automatically adapted to the frequency of the synchronizing pulses.

The high-pass filter HPF preferably consists of a series capacitance C and a transverse resistor R. This filter eliminates the direct current component, taking into account the compensation processes.

The pulse width discriminator PWD consists of a voltage doubler of conventional design with two capacitors C ₁ , C ₂ whose common connection point is connected to earth (or any other suitable fixed potential). They become in resistance and resistance. Although T can be selected to be greater than the smallest period of the synchronization pulses received, this implies that T must not extend beyond the aforementioned maximum and minimum limits if the desired automatic switching is not to be jeopardized. When using z. B. 625 and 819 lines, T should be chosen as the arithmetic mean of the corresponding periods, but it must be ensured that T is not more than

60 819-625
- 819 + 625

= + 13%

70 deviates from the total value.

Indeed, this choice gives better sensitivity than a value T which is equal to 13% less than the smallest period, that is to say 819 lines. Of course, if T is chosen to be greater than this smallest period, the monostable multivibrator must be designed so that it does not in the unstable state

can be influenced by further switching pulses, which should only cause a tilting (into the unstable state) in the stable state of the arrangement. On the other hand, T can e.g. B. be chosen half as large as the above value, ie smaller than the period corresponding to the 819 lines. This is the limit of the percentage deviation too

1875-819
625 + 819

= 73%

ίο

In the illustrated embodiment, in which a distinction is made between two frequencies, the regulating or control arrangement consists of a tube V ₃ , in whose anode circuit the windings of a relay R _{e are} connected and whose grid is connected to the tap t of the potentiometer P.

If the synchronization pulses have the frequency ^ ₁ , the direct current potential at the tap t is such that the tube V _z is biased until it is blocked; the relay R _e is thus not actuated, so and the resonance _{circuit for the frequency Z 1} (not shown) is switched on via the normally closed contacts of the relay in the circuit of the deflection oscillator, also not shown, so that it oscillates _{at the frequency Z 1.}

If the synchronization pulses have the frequency f ₂ , the direct voltage potential at the tap t increases, so that the tube F _{3 is} fully conductive (saturation) and the relay R _{e is} actuated, so that the circuit tuned to the frequency / ^ via the normally open contact in place of the circuit tuned to the frequency Z _{1 is} switched into the oscillating circuit of the deflection oscillator. The deflection generator thus oscillates at the frequency f ₂ .

Although the embodiment shows an arrangement which distinguishes between two frequencies of the synchronizing pulses; However, regulation and control devices CM can of course also be provided which respond to more than two values of the potentiometer tap and switch the deflection generator to more than two frequencies (e.g. a relay with three positions). Likewise, it is of course also possible not only z. B. to automatically switch the line frequency, but also to combine an automatic audio IF switch for the required image-sound carrier distance and, if necessary, to provide positive and negative image modulation coupled with AM and FM modulation.

Likewise, it is also not necessary that electromechanical relay switches have to be used for the control or switching device CM; it can of course z. B. electronic switches (for example, rectifier gate circuits) can also be used. Likewise, the relay shown could be replaced by an ohmic load, and the anode of the tube V _z could be connected to the center point of the primary winding of a first transformer, the secondary winding of which is short-circuited via a capacitor. Each end of the first winding could be connected to one end of the first winding of a second transformer via a rectifier, and both rectifiers could be polarized in the same way. The second winding of the second transformer could be connected in parallel with a capacitor. By using a fixed bias potential at the midpoint of the first winding of the second transformer, the two rectifiers could be made conductive when the anode potential of the tube V _{z has reached} a certain value and could be blocked when it has a different value. In the first case, the capacitor could be switched on via the second winding of the first transformer and switched off in the second case. By switching on the secondary winding of the second transformer in the oscillator circuit, the latter can thus oscillate at two different frequencies, each corresponding to the synchronization signals received.

Even if the invention has been explained on the basis of a specific exemplary embodiment, this is only intended to serve as an explanation, but not to imply a restriction to the illustrated case.

Claims (5)

PATENT CLAIMS: 1. Arrangement for switching the deflection generators of a multi-standard television receiver for receiving transmitters which, with the carrier wave remaining the same, optionally different Use synchronization frequencies, characterized in that the synchronization frequencies distinguishing discriminators feed control arrangements which frequencies the deflection generator automatically bring them in accordance with the respective norm of the received broadcast. 2. Arrangement according to claim 1, characterized in that the different synchronizing frequencies distinguishing discriminators a circuit arrangement each with one controlled by the received synchronization pulses have stable and unstable electrical state, at the output of which by a High pass the DC component which is a function of the character-to-space ratio the received frequencies of the synchronization pulses (and the time constants of the arrangement) representing pulses are eliminated, whereupon by a pulse width discriminator DC potential is generated, which is a function of said ratio of character to space is, and arrangements which the frequency of the deflection oscillator automatically with the size bring this DC potential in agreement controls. 3. Arrangement according to claim 2, characterized in that the high pass from a network with Series capacitor and cross resistance exists. 4. Arrangement according to one of the preceding claims, characterized in that the pulse width discriminator has a voltage doubler circuit formed from two capacitors, the common connection point of which to a Fixed potential is applied and the rectifier connected with the opposite polarity is charged and that a potentiometer of high resistance to those not connected to the fixed potential Assignments of the capacitors is connected, so that the potential at the potentiometer tap is a function of the character-to-space ratio. 5. Arrangement according to one of claims 2 to 4, characterized in that the arrangements for automatic control of the deflection generator frequencies depending on the DC potential of the pulse width discriminator have an amplifier tube, at the Control grid cathode circuit the output of the pulse width discriminator is connected, while in its anode circuit the winding of a relay is switched, and that the amplifier tube either is biased so far that it is through the output voltage of the pulse width discriminator blocked or made conductive so that the Relay is brought into rest or working position and thus the deflection generator on the one or other of the deflection frequencies of the frequencies corresponding to the receiving station switched will. 1 sheet of drawings