DE1006010B - Circuit arrangement for the amplification of two rows temporarily separated in time and occasionally simultaneously occurring pulses - Google Patents

Description

Circuit arrangement for amplifying two rows temporarily in time Separately and intermittently occurring pulses The invention relates a circuit arrangement for amplifying two rows temporarily separated in time and at times simultaneously occurring impulses and for such a union of the amplified pulses that two simultaneous pulses with a smaller one Amplitude as the algebraic sum of the amplified pulses at a common Terminal take effect, especially for the union of reflex pulses and Distance marking pulses in a radio measuring system that works according to the reflection principle to a terminal of a cathode ray tube showing traces of light on its screen.

If you have two series of pulses with temporarily separated and temporarily simultaneous wants to decrease occurring pulses at a common terminal, so you can z. B. let two three-pole tubes work on a common anode resistor and each of the two series of impulses feed one tube to the grid. At the anodes of the two Tubes then enter the impulses, provided they coincide in time, with an amplitude equal to the sum of the individual amplitudes.

Such a solution would, for example, not be satisfactory if the Control grid of a cathode ray tube of a radio meter two the cathode ray light-sensitive, d. H. amplifying signals must be added. It is about thereby about radio measuring devices with a transmitting beam circulating in a horizontal plane and with a cathode ray tube, on whose screen the reflected energy by means of a cathode ray deflected in polar coordinates is displayed. The one The signal at the control grid of the cathode ray tube corresponds to that of the illuminated one Target received echo. The other signal corresponds to a so-called range circle. If the distance of the irradiated target is now equal to the distance, marked by one of the distance circles on the screen, both will fall Signals at the control grid of the cathode ray tube coincide in time. When using a circuit that simply forms the sum of the two signal amplitudes would at the intersection of the trajectory of the irradiated target with the relevant one Distance circle of the Leucbtfleck become undesirably bright and the spot sharpness is below Circumstances are lost, d. that is, the light spot would be undesirably widened.

A circuit has also already become known in which this Addition of the pulse amplitudes does not occur and which is therefore better for the application suitable in radio measuring systems. This known circuit consists of several cathode follower tubes, the work on a common cathode resistor. This circuit does occur the disadvantage to be observed in the first-mentioned circuit no longer shows, but In this circuit, only the largest of two simultaneously occurring pulses is used passed on. The pulse amplitude at the common cathode resistor is the amplitude of the impulses of the two rows, as long as these impulses arrive individually, linear proportional when the cathode follower tubes are blocked in the idle state.

If the tubes are not completely blocked in the idle state, then the small impulses are passed on with a lower gain than the large impulses.

In the case of radio measuring devices, however, the amplification ratios are exactly the opposite desirable, because weak echo signals should be raised and compared to stronger ones not be further disadvantaged.

The main disadvantage of the circuit with cathode followers, however, is that these do not amplify the signal.

The circuit according to the invention combines the advantages of both known Circuits, i.e. signal amplification and non-linear addition, without their disadvantages to own. In addition, weak single impulses are to some extent preferably reinforced because they are in the steepest part of the tube curve.

The circuit arrangement according to the invention for amplifying two Rows of impulses that occur temporarily at different times and at times at the same time and to combine the amplified impulses in such a way that two simultaneously occurring Pulses with a smaller amplitude than the algebraic sum of the amplified Pulses at a common terminal take effect, especially for the union of retroreflective pulses and distance marking pulses in one according to the retroreflective principle working radio measuring system on a terminal of one of the traces of light showing on its screen Cathode ray tube, is characterized in that the two pulse trains the Grids of two separate electron rollers, each with its own anode resistance have, are fed with negative polarity and that between the anodes of this Tubes a rectifier is located, the cathode of which is connected to the aforementioned terminal is.

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

Fig. 1 shows a schematic circuit diagram, which is a preferred represents asymmetrical embodiment of the invention. Fig. 2 includes a Family of curves for a better understanding of the mode of operation of the invention, and Fig. 3 contains a symmetrical circuit to which the curves in FIG. 2 belong.

In Fig. 1, a first and a second tube 10 and 12 are with the Anodes 14 and 16, the grids 18 and 20 and the cathodes 22 and 24 respectively. The cathodes are both connected to earth. The anode 14 of the first tube 10 rests against it a voltage B +, over a load that results from the series connection of a Resistor 28 and a coil 26 consists. The second tube anode 16 is also via a load branch consisting of a resistor 32 and a coil 30, connected to voltage B +. A rectifier, for example a crystal diode 34, is between the Röliren anoden 14 and 16. Its cathode 36 is with the Anode 14 and its anode 38 are connected to the anode 16.

The sliding contact of a potentiometer 42 is directly on the grid 20 of the second tube 12. Between a signal input terminal 49 and the aforementioned one Grid a capacitor 46 is switched on.

In addition, the circuit still shows the capacitor 48, which is a part represents a circuit supplying a signal b. One terminal of the potentiometer resistor 42 is at point 50 while the other potentiometer terminal is grounded.

A grid leakage resistor is in the usual way between the grid 18 the first tube and earth turned on. Otherwise is a blocking capacitor 70 switched between this grid and a connection point 58 at which the Sliding contact 60 of a potentiometer 62 is connected. The resistance of the Potentiometer 62 is between ground and a signal input terminal 66 at the connection point 68. A capacitor 56 is connected between points 58 and 68. The output size is taken from the circuit at point 72, i.e. H. between the diode cathode 36 and the tubular anode 14, and can, for example, to control the cathode steel a Tube 74 whose control grid 72 'are fed.

The cathode ray tube 74 is supplied with suitable DC voltages from a Voltage source 76 and appropriate deflection voltages supplied from a voltage source 78, to bring the beam on the fluorescent screen 80 to the right place. the Sizes of Switching elements of the circuit shown in Fig. 1 were as follows: The Resistors 28 and 32 were 2 and 3.3 kilo ohms and coils 26 and 30 were each a size of 20 microhenries, the 34 crystal diode was a tube made in the United States States usual type designation IN 34 A, the tubes 10 and 12 were the two Discharge routes in the United States under the type designation 6 J 6 available tube, the resistance 54 was 390 kiloohms, the capacitor 70 had 0.01 microfarads, potentiometers 62 and 42 had total resistance of 75 Ohm resp.

10 kilo ohms, and capacitors 46, 48 and 56 finally had each a size of 47 picofarads.

The coils 26 and 30 are used to compensate for the harmful capacitances in the anode circuit and thus to maintain the pulse shape. The potentiometer 62 and the capacitors 70 are connected in such a way that a certain amplitude adjustment is possible while the capacitor 70 allows some frequency compensation. That Potentiometer 42 and capacitor 46 simultaneously effect compensation and an amplitude adjustment and close the grid circle. The compensation effect can be neglected for the purpose of a qualitative explanation of the invention. In addition, for the purpose of this explanation, one can use the stray capacitances and the electrode capacitances to neglect. The signals arriving at the grid 18 are in the negative direction lying impulses which, after being converted into positive impulses, are sent to the control grid a cathode ray tube in a position indicator working with a radio measurement can be fed to the display of illuminated targets. The deflection circles of the cathode ray tube must deliver radial deflection lines, which at points with a given Radius from the center of the screen must be reinforced. The radial direction of the deflection lines must coincide with the direction of the scanning beam at every instant. The distance marks appear as circles on the tube screen because the beam the cathode ray tube is amplified at this point.

It is first assumed that the signals a, which the irradiated Aiming correspond to the grid 18 at a point in time that is from the range marker deviates, arrive. The signals for the distance marking are the signals b. The signals a are fed to the grid 18 as negative pulses because of a decrease of the anode current in tube 10 produces a positive pulse at point 72 and on the output lead generated and therefore a visible spot on the tube screen 80 is formed. The Sigaalei b are also negative impulses and call as long as they are not with the signals a coincide, likewise a decrease in the current in the tube 12 and thus a positive pulse emerges at the anode 16. So if the signals b do not match the signals a coincide, the tube 12 carries a current which both through its load branch 30, 32 is conditioned as well as by the load branch of the tube 10, namely the Branch 26, 28, since the current through this latter branch runs via the diode 34. The entire load on the tube 12 is therefore made under these circumstances the parallel connection of the load branches of both tubes. However, that generated by the diode34 flowing current creates a positive pulse at the output terminal and at the Connection point 72 as well as a distance mark on the screen 80. It is to be noted that that the output pulse at 72 due to the signal b among them Under certain circumstances only by the reduced current through the resistor 28 and the coil 26 is conditional.

It is now assumed that two pulses of the signal a and des Signal b coincide and that the signal a at the grid 18 is about as large or is greater than the signal b on grid 20. In these circumstances, the positive Output pulses due to the current of the tube 10 have a voltage at point 72 of at least the same size as the voltage at the anode 16. The diode 34 therefore does not carry any Current, since no output voltage is controlled due to the signal b. if however, the signal amplitude b is that of the signals by a certain amount exceeds, they carry over to the output voltage according to their excess the signal amplitude a at. It will be understood that because of the contact voltages and for similar reasons, the voltage at the anode 16 that at point 72 by one must exceed a certain amount before actually adding the coincidence signal occurs. This amount can be exceeded by a suitable, not shown Bias circuit for the crystal diode 34 can be set.

It can be seen that the circuit is a particularly advantageous device represents for the mixture of negative impulses to be amplified. Because it was found practically that the circuit according to the invention is a very special and has a very desirable quality. When the targeted target is on the screen of the cathode ray tube and thereby cutting the circles of distance are for the observer can also see the individual lines at the point of intersection.

The circuit according to the invention can also be used for other than those mentioned Purposes.

For example, if signals are applied to the grating 18 of the tube 10, the gain and the linearity of the gain by one of the grating 20 The voltage applied to the tube 12 can be influenced very easily. With suitable Choice of the two tubes and with a suitable choice of the switching elements, in particular of resistors, the given non-linearity of the signal can have various functions two variables can be adjusted. Furthermore, if the grid 18 of the tube 10 a DC voltage or a slowly changing: voltage is supplied the negative signals amplified by the tube 12 at a voltage cut off, which is determined by the voltage applied to the grid 18 of the tube 10 is. Negative signals below this amplitude are not transmitted. That happens with regard to the cutting process is analogous to the use of a grid bias on a single tube to block positive signals under a certain one Amplitude. However, the inventive circuit iii is primarily for negative Determines the input voltages and, secondly, prevents positive overdriving of the negative input signals to the tube 12. Therefore, in the illustrated Using the circuit the target and the range circle or the return signal and the distance signal move very close together without these signals on the The screen of the display tube interfere with each other.

The family of curves according to FIG. 2 illustrates the properties of in Fig. 3 shown embodiment of the invention. The circuit according to FIG. 3 differs from that in Fig. 1 insofar as Fig. 3 is symmetrical with the exception of the diode Circuit represents. The connection of the individual switching elements and the mode of operation does not need to be described as the circuit is clearly shown in FIG the description of the mode of operation on the basis of FIG. 1 had been given. In Fig. 3, the sizes of the switching elements used are as follows: The coils 84 and 86 are 20 microhenries each, the resistors 88 and 90 each 2 kilo ohms, the capacitors 92 and 94 each 0.1 microfarads, the capacitors 96 and 98 each 47 picofarads, the resistance 100 is 75 ohms, resistor 102 is 72 ohms, and resistors 104 and Finally, 106 have a size of 390 kilo ohms each. The tubes 108 and 110 are the separated three-pole tube parts of a tube 6 J 6. The crystal detector 112 was of type IN 34. The input voltages are square negative pulses. the Voltage amplitudes in Fig. 2 apply to the peak values of the input and output voltages.

PATENT CLAIMS: 1. Circuitry for amplifying two Rows of impulses that occur temporarily at different times and at times at the same time and to combine the amplified impulses in such a way that two simultaneously occurring Pulses with a smaller amplitude than the algebraic sum of the amplified Pulses at a common terminal take effect, especially for the union of retroreflective pulses and distance marker pulses in one according to the retroreflective principle working radio measuring system on a terminal of one of the traces of light showing on its screen Cathode ray tube, characterized in that the two pulse trains the grids two separate electron tubes, each with their own anode resistance, with negative polarity and that between the anodes of these tubes a rectifier is located, the cathode of which is connected to the mentioned terminal.

Claims (1)

2. Arrangement according to claim 1, characterized in that the rectifier is a crystal rectifier. 3. Arrangement according to claim 1 or 2, characterized in that the tubes are operated from the same anode voltage source. 4. Arrangement according to one of the preceding claims, characterized in that that the return beam pulses are fed to that tube at whose anode the rectifier cathode lies. Considered publications: "Vacuum Tube Amplifiers" (Vol. 18 of the "Radiation Laboratory Series"), p. 101.