DE1112105B - Circuit arrangement for generating an electrical pulse train - Google Patents

Description

Circuit arrangement for generating an electrical pulse train Die The invention relates to a circuit arrangement for generating an electrical pulse train, which is intended in particular for remote measurement purposes.

For remote transmission of a measured variable with the help of an electrical pulse train it has proven to be advantageous to convert the measured variable into a pulse sequence with a to convert the period duration proportional to the measured variable, as it is a very fast one and remote measurement highly insensitive to distortion is obtained. To several To be able to remotely transmit measured variables one after the other on a single C7 transmission channel, furthermore, a pulse transmitting device has been found to be desirable which can generate a series of pulses in which the pulse duration is proportional to a measured variable and the duration of the pause is proportional to another measured variable.

The invention aims to create a simple and cheap Circuit arrangement with two inputs that generate an electrical pulse train, in which the pulse duration is proportional to one at the one with great accuracy Input connected DC voltage is while the pause duration with great accuracy is proportional to a DC voltage connected to the other input. if the two inputs of the device are connected to each other and a direct voltage is connected to the inputs interconnected in this way, the device becomes apparently produce a series of pulses in which the period is proportional to the connected DC voltage.

The device according to the invention is essentially characterized in that that it contains two capacitors connected to a substantially constant source of direct current are connected, the one capacitor through a diode at one input the device is connected in such a way that the diode is then conductive when the voltage of the capacitor is the DC voltage connected to this input exceeds, while the other capacitor through another diode in corresponding Way connected to a different input, and that capacitors in parallel are connected to two transistors, so that each transistor from the current through the capacitor is controlled to which the other transistor is connected in parallel is.

According to the invention, the transistors are advantageous for each of the Capacitors connected in series, each with a biased diode, and the arrangement according to the invention can also contain a pulse-sending relay, which is controlled by the currents through the transistors. To generate electrical Pulse trains are multivibrator circuits known that generate a pulse train, whose frequency is proportional to a single DC control voltage. With these known circuits, the sweep frequency of the multivibrator depends on the discharge time of the capacitors of the multivibrator circuit are determined, and these capacitors are discharged against the variable DC control voltage, so that the discharge speed depends on the control voltage. The discharging of the capacitors will continue interrupted when the capacitor voltage equals the reverse voltage of the multivibrator tubes will. A device that generates an electrical pulse train, its pulse duration and pause duration can be controlled independently of one another by one DC voltage each is not known, however.

The invention is described in more detail below with reference to the drawing, which represents an embodiment of the invention.

The device shown in the drawing contains two capacitors 1 and 2, which are connected in series, each with a large resistor 3 and 4, to a constant DC voltage at 5. The capacitor 1 is connected via a diode 6 to one input terminal pair 7 and the capacitor 2 via a diode 8 to the other input terminal pair 9 of the arrangement. The arrangement also contains two transistors 10 and 11 which are connected in series with one diode 12 and 13 each in parallel with one of the capacitors 1 and 2 each. The base circuit of the transistor 10 is connected in parallel to a diode 14 which is connected in series with the capacitor 1 , while the base circuit of the transistor 11 is connected in parallel with a diode 15 which is connected in series with the other capacitor 2. The diodes 12 and 13 are biased in that a direct voltage connected at 16 through the two windings 17 'and 17 "of a polarized relay 17 and the resistors 18 and 19 with the connection points 20 and 21 between the diodes 12, 13 and transistors 10 , 11. The relay 17 has a contact 17a for transmitting a series of pulses on the outgoing line 29. The transistors 10, 11 are each connected in parallel with a capacitor 22, 23 and their base electrodes are connected to one through resistors 24, 25 positive DC voltage is connected at 26. Finally, two capacitors 27 and 28 are connected in parallel to one of the inputs 7 and 9 of the device.

In the following description of the function of the device, it is assumed that two DC voltages E1 and E1 are each connected to one of the inputs 7 and 9 of the device and that these DC voltages are lower than the voltage connected to 16. It is further assumed that at a certain moment the capacitor 1 is charged by a direct current of 5 through the resistor 3. Part of this charging current flows through the transistor 10, while the remaining part flows through the resistor 24 to the terminal 26 . The part of the charging current of the capacitor 1 flowing through the transistor 10 keeps the transistor 10 fully conductive, which is why its collector electrode, ie the point 20, assumes approximately zero potential. The diode 12 also becomes conductive, and the capacitor 2 is consequently short-circuited by the diode 12 and the transistor 10. Since no charging current flows through the capacitor 2, the transistor is not kept fully conductive, which is why its collector electrode, ie point 21, approximately assumes the potential -26V. As a result, the diode 13 is also non-conductive as long as the voltage of the capacitor 1 does not exceed -26 V, which is why no part of the current through the resistor 3 can flow through the diode 13 and the transistor 11. As long as the voltage of the capacitor 1 does not exceed the voltage E1 connected to the input 7, the diode 6 is also non-conductive, which is why the charging current of the capacitor 1 is clearly determined by the voltage at 5 and the resistor 3. Since the transistor 10 is completely conductive, a current of 16 flows through the relay winding 17 ', the resistor 18 and the transistor 10 to earth. In contrast, only the leakage current of the transistor 11 flows through the other relay winding 17 ″, which is why the contact 17a of the relay is closed and a DC voltage pulse is transmitted on the outgoing line 29 of the device it is prevented from controlling the transistor 11. Since the charging current of the capacitor 1 is approximately constant, the voltage of the capacitor 1 rises linearly with time until it has the same value as that connected to the input 7 Voltage El reached. The pulse transmitted on the outgoing line 29 consequently has a duration which is proportional to the voltage El connected to the input 7.

When the voltage of the capacitor 1 reaches the same value as the voltage El, the diode 6 becomes conductive. In this case, the capacitor 27 directly takes over a large part of the current through the resistor 3, which is why the charging current of the capacitor 1 drops almost instantaneously to a small value. Since the voltage connected at 26 and the resistor 24 are dimensioned such that this residual current flows through the resistor 24 to 26 , the transistor 10 is throttled at the same time. At the same time, its collector electrode, ie point 20, assumes a negative potential, which is why diode 12 is also blocked. A charging current therefore begins to flow from 5 through resistor 4 to capacitor 2, which is now being charged. This charging current controls the transistor 11, which thus becomes conductive, with its collector electrode, ie the point 21, approximately assumes the potential zero. The diode 13 also becomes conductive, which is why the capacitor 1 is short-circuited by the diode 13 and the transistor 11 and is consequently discharged. The discharge current which flows through the diode 14 causes a low positive potential at the base electrode of the transistor 10, so that this transistor becomes completely non-conductive with certainty. Because the transistor 10 becomes non-conductive, the current through the relay winding 17 'decreases until only the leakage current of the transistor 10 flows through the winding, while the current through the other relay winding 17 ″ increases because the transistor 11 becomes conductive. The relay contact 17a consequently opens, and a pause is sent on line 29, which pause lasts as long as the capacitor 2 is charged.

The charge of the capacitor 2, whose voltage is approximately linear with As time increases, it continues until the voltage on the capacitor has the same value like the voltage E. connected to input 9. The duration of the Line 29 emitted pause is consequently directly proportional to that at the input 9 connected voltage E.,. If the voltage of the capacitor 2 is E., reached, the diode 8 becomes conductive, the capacitor 28 almost instantaneously a large part of the current through the resistor 4 takes over. This is what happens a course corresponding to the process described above with the result that the diode 13 and the transistor 11 are non-conductive, so that the charge on the capacitor 1 starts again, while the diode 12 and the transistor 10 become conductive and short circuit the capacitor 2, which is discharged. The relay 17 switches again, so that its contact 17a is closed and a new pulse is sent out will.

The above-described switching from the charge of one capacitor to the charge of the other happens very quickly, which is why the duration of the generated pulses and pauses is proportional to the DC voltages connected to the inputs with great accuracy. Of course, it is not necessary that the series of pulses generated is removed with the aid of a relay. B. can be taken as the voltage drop across one of the resistors 18 and 19 . The primary function of the biased diodes 12 and 13 is to prevent the leakage current flowing through the non-conductive transistor from the voltage source 5 from flowing through one of the resistors 3 and 4, which would make the charging of the capacitors 1 and 2 less accurate. The diodes 12 and 13 mean that the voltages of the capacitors cannot exceed the voltage connected at 16, and therefore also serve as overvoltage protection for capacitors 1 and 2 and transistors 10 and 11. They also have the effect that, if no voltage is connected to inputs 7 and 9 or there is an interruption in the inputs, the device continues to generate a series of pulses with a pulse and pause duration proportional to the DC voltage connected to 16.

The capacitors 27 and 28 have, as mentioned, the task of taking over part of the current flowing through the resistor 3 or 4 immediately when the diodes 6 and 8 become conductive, so that a momentary strong reduction in the charging current of the capacitors 1 and 2 and thus quick and accurate switching is obtained. Without the capacitors 27 and 28, the charging currents of the capacitors 1 and 2, when the diodes 6 and 7 become conductive, would decrease relatively slowly with a time constant that depends on the size of the capacitors 1 and 2 and the normally relatively large internal resistances of the voltage sources connected to the inputs 7 and 9 is determined, which is why the switching would be carried out relatively slowly and less precisely and the accuracy of the device would be impaired. The capacitors 27 and 28 also cause the voltages connected to the inputs 7 and 9 to be flattened if they contain an alternating voltage component.

The diodes 14 and 15 have the task of controlling the charging currents through the capacitors 1 and 2 to flow through the transistors 10 and 11 and this thereby to keep fully conductive. At the same time, they offer very little resistance for the discharge currents of the capacitors, so the capacitors with security be fully discharged between each charge. The capacitors 22 and 23 have the main task of the transistors 10 and 11 against the overvoltages protect that arise in the circuits of the relay 17. Prevent at the same time that brief disturbances at the inputs 7 and 9 result in an incorrect switchover of Charge of one capacitor can cause charge of the other.

Claims (3)

PATENT CLAIMS-1. Circuit are controlled to produce an electric pulse sequence whose pulse widths and pulse intervals of each of a DC voltage independent of each other, characterized in that the arrangement of two capacitors (1, 2) which are connected to a substantially constant DC power source (5), wherein the a capacitor (1) is connected through a diode (6) to an input (7) in such a way that the diode (6) becomes conductive when the voltage of the capacitor (1) exceeds the DC voltage (El ) exceeds, and the other capacitor (2) is connected in a corresponding manner to another input (9) through another diode (8), and that capacitors (1, 2) are connected in parallel to two transistors (10, 11), such that each transistor is controlled by the current through the capacitor to which the other transistor is connected in parallel. 2. Circuit arrangement according to claim 1, characterized in that the transistors (10, 11) are connected in parallel to the capacitors (1, 2) in series, each with a biased diode (12, 13). 3. Circuit arrangement according to claim 1, characterized in that it is a pulse-sending relay (17) which is controlled by the currents through the transistors (10, 11). In Documents considered: German Auslegeschrift No. 1042641; “Proc. of the IRE ", February 1948, pp. 277-280; »Waveforms« by B. Chance, v. Hughes et al. a., 1949, McGraw-Hill-Book Co., New York, pp. 193 to 195.