DE756555C - Coupling circuit between signal source and load circuit - Google Patents

Description

The invention relates to coupling means for tube circuits for the transmission of Vibrations of a wide frequency band including the direct current component.

As is well known, changes in the brightness of the picture are made in television systems a slowly changing direct current is shown. To get an accurate working one To ensure the television receiver, it is necessary that the playback device, for example a cathode ray tube, the image signals within a wide frequency range with the inclusion of the direct current component, so that one changes the mean brightness of a scene on the transmitter receives a corresponding change in the picture.

It has now sometimes been observed with television receivers that if the picture brightness deviates from the mean and becomes either very light or very dark, a Contrast distortion occurs. This distortion is due, among other things, to that the image display device

In the maximum dark or bright area, non-linear parts of the • rendering characteristics owns. Also change if, for example, the rectifier tube directly init a television signal amplifier tube is connected, in turn directly to the picture display device Cherishes, all - fluctuations in the operating voltage of this tube the mean direct current potential of the control electrode of the image display device and thus the average image brightness.

It is already known that a Braun tube has the direct current component and the Supply AC components via a potentiometer and this potentiometer simultaneously with the bias for the brightness control electrode of the Braunscheu ■ Adjust the tube. This adjustment has been made, for example, in such a way that that the black level of the image brightness signals is always on the lower kink of the ■ Brightness control characteristic was, regardless of the brightness value, with which the brightest Image areas were reproduced. The ver | position of the potentiometer kanu also like this ■ happen that at the same time the bias of the cathode ray tube is changed so that between the sum of the highest and lowest brightness value and the difference a certain relationship is maintained between these two brightness values. In all cases however, the ratio of the DC component to the AC component is au the Braun tube exactly the same as the signal source.

The invention relates to a coupling circuit between the signal source and the load circuit for the transmission of vibrations within a broad frequency band including the direct current component, especially for television purposes, and is characterized by the fact that the coupling circuit is frequency-dependent in addition to ohmic resistances Contains switching elements, such that the ratio between direct current and alternating current components, which on the Load circuit is transmitted regardless of the fluctuations in the direct current component that occur at the output of the signal source and a permanently adjustable has a larger or smaller value than at the signal source.

The signal source can be an image signal rectifier, for example an anode rectifier or a television amplifier tube, the load circuit a cathode ray tube or an amplifier stage.

In one embodiment of the invention, this coupling network consists of a series connection of a resistor R. _Ä and a capacitor 15 between the anode and cathode of an amplifier or rectifier tube. Another resistor R _{2 is} parallel to the capacitor : the common connection point of both resistors is directly at the input electrode of a cathode ray or glow electrode tube. The value of these resistors is chosen so that approximately the following equation "applies:

DC component IGK \ R _s

AC component \ WK) R ₂ - R _{: i} '

In a further circuit according to the invention, an anode resistor R _A and a decoupling resistor R _{1 are} located in the anode line of the amplifier or rectifier tube; with a capacitor, the arrangement being such that the following equation applies:

GK R ₁₁ -r Ra

Ra

R, -

The invention will now be described in more detail with reference to the drawings will.

In Fig. Ι the tube 1 represents an ordinary one Two-pole rectifier tube. The cathode 3 is grounded, while the anode 2 Via the secondary winding 5 of a high-frequency transformer with the grid 10 an amplifier tube 8 is in communication. This grid 10 is connected via a resistor 7 and a small capacitor 6 connected to ground. High frequency signals arrive Via the primary winding 4 of the high-frequency transformer to the secondary winding 5. The screen grid 11 of the tube 8 is connected to a positive potential point 14 at which also the anode resistor 13 is connected. The cathode 9 of the tube 8 is grounded. The control grid 20 of the cathode ray tube 18 is across the resistor i6 with the Parallel capacitor 15 at the anode 12 of the tube 8. In addition, the grid is the cathode ray tube grounded through a resistor 17. A battery 21 provides a suitable one Cathode ray tube bias. The negative pole 22 of the high voltage source is grounded. The tube can also be preloaded by other known means, for example by tapping on a potentiometer, parallel to the high voltage source obtain.

The demodulated television signals arise at the resistor 7 and arrive in this way the grid of the tube 8 that the peak whites of the image have negative pulse peaks Generate tubular grids. The signals are then amplified through the tube, in theirs Phase reversed and to the control grid of the

Cathode ray tube supplied. According to the

GK

Invention becomes the relationship

WK

by

The appropriate choice of the values for capacitor 15 and resistors 16 and 17 is determined in such a way that the following equation applies to the ratio of direct current component and alternating current component:

GK

whereby

WK Z ₁ + R _s

R ₃ = I ₇ ,

τ>. γ

₃ 7

(R ₂ = i6, C ₁ = 15). With this arrangement, the DC component is less - than the AC component and that

C ¹ IC

Ratio ™ =. approximately equal to the value

of resistance 17 divided by the sum of the values of resistors 17 and 16, assuming that for AC frequencies the resistor 16 with the parallel capacitor 15 can be neglected can.

In the arrangement according to Fig. 2 there is a decoupling resistor 23 with a decoupling capacitor 24 is provided in the anode circuit of the tube 8. Besides the decoupling of the high voltage source, this means Resistance improves the frequency characteristics of the coupling for the alternating current component. Any loss of frequency near the line frequency caused by the increase in the resistance of the coupling 16, 15 is due to the gain in gain due to the increase in the resistance of the circuit 13, 23, 24 balanced.

It can be seen that the behavior of the circuit from very high frequencies down to frequencies in the vicinity of the frame frequency is primarily determined by the time constants of resistor 13 and capacitor 24 for the anode circuit and by the time constants of capacitor 15 and resistor 17 for the grid circuit will. If these time constants are made the same, the behavior of the circuit can be made the same from high frequencies down to a certain frequency which is below the frequencies ¹ determined by the values of the two time constants. At even lower frequencies, the behavior is determined by the time constants of resistor 23 and capacitor 24 for the anode circuit and capacitor 15 and resistor 16 for the grid circuit. In order to make the ratio between direct current and alternating current components greater or less than 1, it is therefore necessary to ensure that the time constants of 23 and 24 and of 15 and 16 are different from one another. As an approximation, assuming that the apparent resistances of capacitors 15 and 24 can be neglected for alternating current:

Cr K

R-

17th

17th

In an arrangement according to Fig. 2, there is a value for the direct current component of 50% if the individual coupling elements have the following value:

Resistance 13 1000 ohms,

Resistor 23 4000 ohms,

Capacitor 24 2.0 microfarads,

Capacitor 15 0.02 microfarads,

Resistance 16 0.9 megohms,

Resistance 17 0.1 megohms.

In Fig. 3 another embodiment is shown in which the anode rectifier is directly coupled to the cathode ray tube. The grid 27 of the quadrupole tube 25 is via the secondary winding 30 of a high-frequency transformer with the grounded negative pole 53 of the high-voltage source tied together. The high frequency signals from preceding amplifier stages may be passed through the primary winding 31 of the High-frequency transformer are fed. The cathode 26 of the rectifier tube 25 is through the resistors 32, 34 and 35, which are parallel to the high voltage source 53, 54 lying, positively biased. The screen grid 28 is given a suitable positive Potential from the junction of resistors 34 and 35, with capacitors 33 and 36 are provided for decoupling the cathode or the screen grid. The anode 29 of the rectifier tube is connected to the positive pole 54 of the high-voltage source via the filter sink 37 (which is caused by the damping resistor 38 is bridged) and the resistors 39, 40 and 44 are connected. The resistor 42 and the capacitor 43 are used for coupling the deflection generators (not shown) with the rectifier tube. the AC components of the television signal become the cathode 48 of the cathode ray tube 49 is fed through the capacitor 41, which is connected to the connection point of the anode resistors 39 and 40 is connected. The cathode 48 of the tube is directly connected to the anode circuit resistor 44 across the Resistor 45 and connected to earth via resistor 47. The DC path between the anode of tube 25 and the cathode 48 of the cathode ray tube is controlled by the choke coil 37 and the resistors 39, 40 and 45 made. The con-

capacitor φ has sufficient capacitance to allow any AC component at the junction of resistors 40 and 44 to pass through. The actual positive potential at the cathode 48 of the cathode ray tube is therefore determined by the voltage source 53, 54 and the effective resistances 44, 45 and 47. The grid 50 of the cathode ray tube is led to a suitable potential point on the potentiometer 51, which is connected in parallel to the high voltage source. The capacitor 52 has a large capacitance and is located between grid 50 and earth. The capacitor 55 lying parallel to the high voltage source also has a large capacitance.

The television signals are rectified by the anode rectifier, its Anode potential drops according to the carrier intensity. One must therefore use these potentials of Feed the cathode to the cathode ray tube so that the carrier modulation increases means an increase in the light intensity on the fluorescent screen of the tube. Since the Synchronization pulses are at the lower bend of the rectifier characteristic, they will their amplitude is reduced compared to the image signals. To make up for this, one takes the synchronizing pulses in the anode circuit between the choke 37 and the resistor 39, while the image signals between the connection point of the resistors 39 and 40 are tapped. Since you can safely make the resistance 44 much higher than the resistance 40, the gain of the DC component can be made much larger than the gain of the AC component. Formed by means of the potentiometer from resistors 45 and 47, it is possible to determine the ratio between direct current and to change the alternating current component so that it is greater or less than 1 at the cathode ray tube • as desired will.

If for some reason the value of resistor 44 is not very much can be made larger than the value of the resistor 40, you can also make the resistor 45 with the connection point of the resistors 40 and 39 or also with the connection point of the resistor 39 and the coil 37, whereby one then also the DC component is used in these resistors.

In Fig. 4 an arrangement is shown, the images of particularly high quality for Supplies for television purposes. The main difference compared to the ones described so far Arrangements are to make use of the very high input resistance as it results from use a tube with a so-called follow-up cathode. This tube forms a path in the coupling network for the alternating current component. It is bridged by a resistor that provides a path for the direct current component as it is is described elsewhere.

The signal reaches the two-pole rectifier 56 through the high frequency input transformer 57. A load resistor 58 lies in the cathode lead of the two-pole tube 56 and is directly connected to the control grid a screen grid amplifier tube 59, which together with the two-pole tube receives a negative bias through a resistor 58. The anode lead of the Tube 59 contains resistors 60 and 61 which correspond to resistors 13 and 23 in Fig. 2 and a decoupling capacitor 62. The image signals appear at the Anode of tube 59 in the positive sense, and this anode is directly connected to the cathode one Cathode ray tube 63 connected through a resistor 64. The cathode is over another resistor 65 at the negative pole of the high voltage source. The resistances 64 and 65 correspond to resistors 16 and 17 in Fig. 2. The anode of the Tube 59 is connected to the control grid of tube 67 via a capacitor 66, which has a trailing cathode. The grid of tube 67 is across the bleeder resistor 68 connected to the common point of resistors 69 and 70. The cathode of this tube is through a capacitor 71 coupled to the cathode of the cathode ray tube 63.

It can be seen that a direct current path for the rectified and amplified signals, as they come from the tube 59, up to the cathode of the cathode ray tube 63 is. The AC path is formed by the capacitor 66, the tube 67, and the capacitor 71. The time constant the coupling through capacitor 66 and resistor 68 is in view of the dimensioned lowest frequencies, and the resistors 60, 61 and 64, 65 have such Size that the following equation is fulfilled:

GK R ₆₁ + R ₁ WK 1

Rc

R ₁₁

The arrangement can also be modified by having the resistor 64 in parallel to the capacitor 66 puts. In this case, the capacitor 71 remains off, so that a direct current connection between the cathode of the tube 67 and the cathode of the Cathode ray tube consists.

If the invention is also with reference to the coupling of a hot cathode tube with a cathode ray tube has been described, it can just as easily be used for coupling to use another hot cathode tube. It was in the previous description assumed that the DC component of the signals in the rectified Signals is present, but can

ίο you can also use the invention if the Direct current component is only introduced again, as it is already known per se is. So z. B. in Fig. 2 an audio tube instead of the directly coupled amplifier tube 8 can be used. In this case a capacitor is in the line from the input terminal to the control grid the rectifier tube, this capacitor being in conjunction with the grid resistor has a time constant that is large compared to the time intervals between the individual synchronization pulses. When the signal is supplied so that the synchronization impulses are in the positive direction, is due to the interaction of the capacitor and the grid resistance introduced the direct current component.

Claims (7)

Patent claims: 1. Coupling circuit between signal source and load circuit · for transmission of oscillations within a broad frequency band under inclusion the direct current component, in particular using a rectifier circuit or an amplifier tube as a signal source and a television receiving cathode ray tube or an amplifier tube as a load circuit for television purposes, characterized in that that the coupling circuit in addition to ohmic resistances · frequency-dependent switching elements contains such that the ratio between direct current and alternating current components, which is transferred to the load circuit, regardless of the fluctuations in the direct current component that occur at the output of the signal source and a permanently adjustable larger or smaller value owns than at the signal source. 2. Coupling circuit according to claim 1, characterized in that the coupling circuit of a between anode (12) and cathode (9) of the rectifier tube or the amplifier tube (8) lying series connection of a resistor (R ₃ ) and a capacitor (15) with a . Parallel resistor (R ₂ ) is formed, and the connection point between the two resistors is directly connected to the input electrode (20) of the cathode ray tube (18) or an amplifier tube and the desired ratio between direct current and alternating current components
GK R ₃ WK R ₂ + R _s WK R ₂ -f-Ä, is (Fig. ι). 3. coupling circuit according to xA.nspruch 2, characterized in that in the 'anode line of the amplifier or rectifier tube an anode resistor (R _A ) and a decoupling resistor (Rf) with a decoupling capacitor (24) and the desired ratio between DC and AC components GK Re -j- Ra R ₃ is (Fig. 2). 4. coupling circuit according to claim 1, characterized in that in the Anode lead of an anode rectifier tube (25) three resistors (39, 40 and 44) lie, the cathode (48) one by tapping on a potentiometer (51, 52) with a negative Control grid supply supplied the cathode ray tube (49) is connected to a potentiometer (45, 47) such that the alternating current component is only on External resistance (40) via a capacitor (41), the direct current component tapped at the positive anode voltage pole (54) upstream resistor (44) via the potentiometer (45, 47) becomes (Fig. 3). 5. coupling circuit according to claim 4, modified so that the direct current component is also tapped at the resistor (40) and optionally at the resistor (39). 6. coupling circuit according to claim 1, characterized in that a tube (6j) with tracking cathode in the transmission path of the AC component between the anode of the tube (59), which represents the _c signal source, and the control electrode of a ■ cathode ray tube is present and that Control grid of the tube (6j) with tracking cathode via a capacitor (66) with the anode of the signal source and the cathode of the tube (67) with tracking cathode via a further capacitor (71) with a control electrode of the cathode ray tube (63), which in turn is connected via a resistor (R ₃ ) on the negative pole the voltage source, and a further resistor (R ₂ ) is arranged directly between the anode of the signal source and the control electrode of the cathode ray tube, an anode resistor (R ₄ ) and a decoupling resistor (Rj;) being in the anode circuit of the control source and the desired ratio between DC and AC components have approximately the following value (Fig. 4): GK
WK Ra 7. Coupling circuit according to claim 6 modified so that the capacitor j (71) omitted and the resistor j (64) parallel to the capacitor (6 (S) ; is laying. See coupling circle according to one of the preceding Claims, characterized in that the ratio between direct current and alternating current components can be changed by changing the design of the coupling elements. To delimit the subject of harvest From the state of the art, the following publication is to be considered in the granting procedure been drawn: Austrian patent specification Xr. 150 570. 1 sheet of drawings © 3233 2.52