DE754557C - Circuit arrangement for the separation of pulses of different duration by converting them into pulses of different amplitudes - Google Patents

Description

To synchronize the two scanning movements (line and image change resp. Line train deflection) in television receivers must have line pulses and line train pulses can be distinguished from one another on the receiver side. The cheap carrier level control because of this synchronizing pulses of the same amplitude that are used differ by their duration.

On the receiver side, these pulses have so far mostly been separated by frequency selection, d. H. a filter was used, for example one connected in series with a capacitor Resistance, and conducted the impulses to be separated in this series circuit to. Since the line pulses have a high frequency, there is a voltage drop across the capacitor low, high at the resistance; with the line pull pulses is because of the low Frequency of the voltage drop across the capacitor is great. So you can use the line train pulses tap at the capacitor because they occur there with a greater amplitude than the Line pulses. A closer look at the mode of operation of the filter element reveals that that; the capacitor is charged by pulses and discharges again in the pause between the impulses. The time con

Stants for charge and discharge are, however, since they are the same in both cases Switching elements acts, the same. It can thus on the capacitor from a previous one Impulse a certain residual charge remains, which leads to the charge of the following Pulses added, so that an increase in the pulse amplitude occurs. Will the am Capacitor tapped pulses are fed to vibration generators, so sensitive Interferences occur by the generator for the line train deflection because of the Residual charge is triggered earlier than would be the case without the residual charge. this is particularly dangerous when interlacing where the lines are in Move the reception image against each other.

The invention describes a circuit arrangement for separating pulses verao of different durations by converting them into pulses of different amplitudes at which the converted impulses according to the duration of the original impulses up to a maximum value, the height of which depends on the pulse duration, increase, but then much faster than they rise, fall to a practically constant minimum value, before the next pulse arrives.

In Fig. I, which shows the pulse mixture transmitted in television, 1 means the black level of the image brightness signals 2. The line change pulses 3 and the image change pulses (if in the following picture change pulses are mentioned, this also includes the line break pulses usual with the interlaced method), of which only two, denoted by 4 and 4 ", all have the same amplitude and lie in the blacker-than-black direction. The picture change impulses have a longer duration than the line change pulses and apply to an interlaced transfer step with two lines per complete picture Image change pulse 4 begins with a line, the pulse 4 ⁰ lies in the middle of a line. The pulse course according to Fig. a plurality of pulses are sent out at the end of each frame; the sync pulses can also be di have the same direction as the image signals; they only have to differ from these in terms of their amplitude. The invention is also not limited to the interlace method.

In the circuit according to Fig. 2, 5 means a screen grid tube with the anodes 6 and 7, of which the xA.node 7 is connected via the resistor 8 to the positive pole of the anode voltage source. All points in the figure that have a plus sign are connected to this voltage source, the negative pole of which is connected to the cathode of the tube 5. The anode 6 of the tube 5 also has a load resistor, which is not shown and which is intended to feed the received line pulses to the line deflection generator. As can be seen from Fig. 1, all synchronization pulses have a steep front. With the exception of "Pulse 4" , these steep fronts repeat at the line frequency, and all synchronization pulses, including the frame change pulses, are fed to the line deflector. The image change pulses 4, with the exception of the pulses 4 °, which occur during the line period, thus support the maintenance of the synchronism of the line deflection.

The received signals (Fig. 1) are now sent to the control grid of the tube 5 in the Way supplied that the synchronizing pulses the grid potential in a positive direction move. The negative grid bias is chosen to be slightly more negative than the locking voltage, so that normally no anode current flows and only the synchronizing pulses running in the positive direction cause an anode current to occur while the image signals are ineffective. Just step on resistor 8 the synchronization pulses on; they are connected to the control grid via the coupling capacitor 9 a screen grid tube 10 is supplied. The control grid of this tube is on one weak positive potential. The amplitude of the synchronization pulses at the control grid of the Tube 10 is so large that each pulse brings the grid potential to a value that is more negative than the value corresponding to the locking voltage, so that through the tube does not flow anode current during the synchronization pulses.

The anode circuit of the tube 10 contains a high resistance 11, and between the The anode and the cathode of this tube are two capacitors 12 and 13 connected in series. The tube 10 is thus during the intervals between the synchronization pulses current-permeable, d. H. the main part of the current in the resistor 11 flows through the tube 10; a small charge goes to capacitors 12 and 13, and on the capacitor 13 there is only a small potential difference. However, when an impulse occurs, d. H. when the tube 10 becomes impermeable, the capacitors 12 and 13 charge across the resistor 11, and the capacitor 13 reaches a potential which the Output potential exceeds and its

Height among others depends on the duration of the pulse. If the impulse disappears, so the tube io becomes permeable again, and the potential difference across the capacitor 13 drops to the initial value relatively quickly, since the cathode-anode resistance of the Tube 10 is less than resistor 11; so it is not one of the blocking time of the tube 10, i. H. residual charge from the pulse more present on the capacitor 13 when the subsequent pulse arrives. Dei The pulse to be taken off at the capacitor 13 therefore falls on the in a much shorter time Baseline when it needed ■ to rise.

The duration of each line change impulse may be 10 ^ s, while the image change impulses have a duration of 40 ^ s and the minimum interval between successive Line and image change pulses also have a duration of 40 ^ s.

In a practical implementation, the time for charging the capacitors was 12 and 13 nearly 200 ^ s, while the discharge was only about 5, as. the converted impulses fell about 40 times faster than they rose, so that none Residual charge on capacitor 13 could be more present when the next pulse arrived.

Under the influence of the circuit described, a sequence of triangular voltage pulses is created. The rise this pulse takes place gradually up to a maximum value that depends on the duration of the given Impulse is dependent. The pulses drop steeply to a constant minimum value, that is to say they arise at the capacitor 13 and are fed to the tube 14. The triangular impulses that. of the image change pulses have a greater amplitude than those from the line break pulses, and the whole train of these converted pulses is taken from the capacitor 13 and an amplitude separator 14 supplied.

The control grid of the tube 14 is opposite the cathode through the resistor 15 and the associated shunt capacitance biased so that only the triangular pulses larger amplitude are able to produce an anodic current. In the starting circle the tube 14 thus occurs a sequence of pulses, each of which is an image change pulse is equivalent to. The output circuit of the tube 14 is e.g. B. with a self-locking Oscillator (not shown) coupled, and each pulse in the output circuit the tube 14 initiates the return of the image changing sawtooth.

In the arrangement according to Fig. 3, the tube 10 ', which corresponds to the tube 10 in Fig. 2, a resistor 16 in the grid circuit and a high resistance 17 in the anode circuit. The tube 10 'may have a similar screen grid tube (not shown) in parallel are switched, which then takes over the task of the anode 6 in Fig. 1; instead of For tube 10 ', a double anode tube can also be used. The received signals are fed to the input terminals 18 in the sense that the image signals are in positive Direction lie; the grid is so 'biased that the image signals in the grid stream lie. As a result of the voltage drop across resistor 16, the actual grid potential remains practically constant. The synchronization pulses reduce the grid potential so far that no more anode current flows. Two capacitors 12 'and 12 are located between the anode and the cathode of the tube 10' 13 'in a row. As in Fig. 2, a train of triangular pulses appears on the capacitor 13 'generated; the impulses corresponding to the image alternating impulses have again greater amplitudes than those corresponding to the line change pulses. The whole episode of Pulses on capacitor 13 'become the grid-cathode route a grid-controlled gas discharge tube 19, the grid through the bias resistor 20 and the associated shunt capacitor so is strongly negatively biased that only the larger amplitude pulses in the tube 19 cause an anode current. The anode circuit of the tube 19 contains a coil 21, one Resistor 22 and a capacitor 23 in the illustrated arrangement; the circle 19 to ■ 23 is self-oscillating and acts in such a way that a potential difference of sawtooth shape occurs at the capacitor 23.

In a modification of the arrangements according to FIGS. 2 and 3, the capacitors 12 and 13 or 12 'and 13' can be connected in series between the anode of the tube 10 or 10 'and the positive terminal of the anode voltage source. If a pulse occurs in an arrangement according to FIGS. 2 and 3, the voltage at the connection point of the two capacitors becomes more positive and the potential difference across the capacitors 13 and 13 'increases. In the modified arrangement, the potential difference across capacitors 13 and 13 'decreases, although the potential at the junction becomes more positive when a pulse occurs. The modified arrangements are basically equivalent to those shown in Figs.

which is the connection point of capacitors 12 and 13 or 12! and 13 'makes more positive to be viewed.

Fig. 4 shows an arrangement in which the synchronizing pulses are converted into triangular voltage pulses of different amplitudes by introducing a charging current in an inductance. In Fig. 4, in the anode circuit of a screen grid tube 24, there is an inductance 25 which is connected in series with a resistor 26. The control grid of the tube 24 is biased so that anode current only flows in the case of synchronizing pulses. The time constant of the coil 25 and the resistor 26 is greater than the duration of an image change pulse, and during each synchronization pulse the tube 24 is current-permeable and a current gradually develops in the coil 25. At the end of the pulse, the tube becomes current-permeable and the charging current ceases, so that triangular voltage pulses appear across resistor 26.

Around the triangular voltage pulses of greater amplitude from those of lesser ones To separate amplitude, a two-pole tube can be used if necessary. One such an arrangement is shown in fig. There a screen grid tube 28 has one Anode resistor 29, while a capacitor 30 is between the cathode and anode. The incoming signal is fed to the input terminals 31 in the sense that the . Image signals lie within the grid current, while the synchronization pulses the Reduce the anode current of the tube to XuIl. As will be in an arrangement as shown in Fig. 3 triangular voltage pulses on capacitor 30 are generated.

These voltage impulses are fed to the \ Vicklung · 32 of a three-coil transformer, with which a two-pole tube 33 and a voltage source 34 are connected in series. The potential of the voltage source 34 is higher than the potential that is at the anode of the two-pole tube as a result of the voltage pulses of lower amplitude on the capacitor 30, but is lower than the potential that the pulses of greater amplitude! is equivalent to. Each of these last-mentioned 1 pulses thus causes a current in the tube 33 and the winding 32. The windings 35 and 36 of the transformer form part of a self-locking oscillator of a known type for the frame rate which the tube 37 contains. If through the _f tube 33 and the winding 2.2 as a result of a ^j - pulse of greater amplitude at the Kon-; capacitor 30 current flows, the pulse is: which consequently on the winding 36-; occurs, the grid circle of the tube 37 of the self-; j blocking vibration generator and thus initiates the return of the sawtooth vibration.

According to Fig. (\ Which schematically shows part of the device for generating the image build-up movement of a television receiver with a cathode ray tube, the anode of a screen grid tube 38 is connected via a resistor 39 to the positive terminal of an anode power source (not shown), the negative terminal of which is connected to earth The control and screen grid circuits are coupled to one another by an iron transformer 40. The tube 38 works as a self-locking oscillator and generates sawtooth oscillations, which are picked up by a capacitor (not shown) which is connected to the terminals 41. The incoming image signals from 1 is applied to input terminals 42 and to the control grid and cathode of a five-terminal tube 43 in such a way that the image signals cause the grid bias to increase in the positive direction Control grids occur while the synchronizing pulses block the anode current. The anode of the tube 43 is connected to the positive terminal of the anode voltage source via two series-connected resistors 44 and 45, while the connection point of these resistors via the capacitor 46 to the input circuit of a self-locking oscillator (not shown) for the line frequency via the line 47 connected is.

If the resistors 44 and 45 are chosen to be sufficiently large, this takes place under the condition a suitable screen grid potential, a separation of the synchronization signals of the image signals through anode current limitation, and the separation is then not dependent on the flow of a grid current. The resistor 48 is retained in this case and serves to reduce the load on the signal source due to the input capacitance of the tube 43. the Resistors 44 and 45 can have values of 50,000 and 200,000 ohms, respectively. Between there is a resistor between the screen grid of the tube 43 and the anode voltage source 49. and a capacitor 50 is located between the screen grid and earth. Effect in operation the synchronization pulses that no current flows in the anode and screen grid circuit can. Synchronization pulses that occur at the anode are the self-locking Vibration generator supplied for the line frequency. During each synchronization

The capacitor 50 receives a pulse which occurs at the control grid of the tube 43 a charge while it is between the pulses via the screen grid-cathode path the tube 43 discharges. At the capacitor 50 a sequence of triangular voltage pulses is generated, each one Has amplitude that depends on the duration of the synchronization pulse and the size of the Capacitor 50 is dependent. The image change impulses thus generate triangular impulses greater amplitude than the line break pulses. The whole sequence of the triangular Pulse lies between the anode and cathode of the two-pole tube 51. The cathode this tube is connected to the junction of resistors 52 and 53 and consequently positively biased towards earth. The amount of this bias becomes so much

zo selected to be greater than the constant anode potential of the two-pole tube, i.e. H. the potential on the screen of the tube 43 in the absence of synchronization pulses that in the tube 51 current flows only when a triangular pulse resulting from an image change pulse occurs. The tube 51 is in series with a winding of the transformer 40. When a picture change pulse occurs at the grid of the tube 43, a current pulse flows through the two-pole tube and through the transformer winding, and the • self-locking vibration generator kicked off in this way.

Claims (6)

PATENT CLAIMS: 1. "Circuitry for separating pulses of different durations Conversion into pulses of different amplitudes, characterized in that the converted pulses accordingly the duration of the original impulses increase up to a maximum value, the height of which depends on the impulse duration, but then in less time than the increase requires, to a practically constant one Minimum value drop before the next pulse arrives. 2. Circuit arrangement according to claim i, characterized in that the to be converted impulses with negative polarity the control grid of a screen grid tube (10, 10 ', 28) are supplied, in the anode lead is a resistor (ii, 17, 29) located while a Capacitor (30) or a series connection of capacitors (12, 13 or 12 ', 13 ') between the anode on the one hand and the negative or positive pole of the Anode voltage source on the other hand is switched on in such a way that the screen grid tube during the duration of the pulses are blocked, but current-permeable in the pauses between the pulses is. 3. Circuit arrangement according to claim i, characterized in that the to be converted impulses with negative polarity the control grid of a screen grid tube (43), in the screen grid circuit of which there is a resistor (49), while between the screen grid and the negative pole of the anode voltage source, a capacitor (50) is switched on in such a way that the Screen grid tube is blocked for the duration of the impulses, in the pauses between the impulses, however, screen grid current leads. 4. Circuit arrangement according to claim i, characterized in that the to be converted pulses with positive polarity are fed to the control grid of a tube (24) in the anode lead a resistor (26) and a choke coil (25) are connected in series in this way! that the current in the reactor depends on the duration of the impulses to be converted. 5. Circuit arrangement according to claims 2 to 4, characterized in that that screen grid tube (10 ', 24, 28, 43) either through a series resistor (16 in Fig. 3, 48 in Fig. 6 or the grid series resistor of the tube 28 in Fig. 5) in front of its control grid or by a corresponding one negative grid bias (on the tube 24 in Fig. 4) also to separate the pulses to be converted from the image content voltages is used. 6. Circuit arrangement according to claims ι to 5, characterized in that that the converted pulses for the image change by a biased Rectifier tube (33, 51) from the converted pulses for the line change be separated. To differentiate the subject matter of the invention from the state of the art, the granting procedure the following publications have been considered: Austrian patent specification No. 144309; French patent number 742 671. 1 sheet of drawings © 5570 11.52