DE1166254B - Monostable transistor pulse generator with a delay chain - Google Patents

Description

Monostable transistor pulse generator with a delay chain Die The present invention relates to a monostable transistor pulse generator with a delay chain for generating pulses of a given duration as a result of a Input signal.

Pulse generators of this type are already known. In the endeavor the speed of operation of electronic pulse circuits - like them, among other things also widely used in electronic computing and data processing systems come - to increase, you are faced with the task of creating pulse generators to create what impulses of short but well-defined duration, with steep Ability to generate edges and the highest possible repetition frequency. the Known pulse generators are not able to meet the high requirements to meet, as they have recently especially in the impulse technology of the digital Calculating machines are required. It is also desirable in numerous applications at the output of a pulse generator signal level of the same order of magnitude obtained as the level of the input signal. This is particularly necessary if one has several pulse stages in a circuit arrangement, in which the same or equivalent electronic components are used, must be connected in series. With the previously known pulse generators, this is generally only possible with the interposition of special equalizing circuits for potential and signal level adjustment possible. Apart from the fact that such compensating circuits the circuit complexity is not insignificant increase, they also compromise those achievable with such impulse posture arrangements maximum working speeds.

With the monostable pulse generator of the invention it is possible to generate short-term pulses of high edge steepness, e.g. B. with rise times on the order of 2 to 3 nanoseconds.

With the pulse generator according to the invention, short-term pulses of well-defined length, the signal level of the output pulse is of the same order of magnitude as the level of the input signal.

The repetition frequency of the output pulses from the pulse generator can be chosen very high, e.g. B. on the order of 10 MHz or above.

The pulse generator of the invention is further designed; that the duration of the output pulses solely through the specified but selectable length the delay line used is given and thus well defined and that this pulse duration independent of any other parameters of the pulse generator is e.g. B. the properties of the electronic components used, transistors and the like, which can change over time.

The one-shot pulse generator according to the present invention draws is made up of a first transistor of a first conductivity type in a collector circuit, whose collector is connected to one pole of a centrally grounded voltage source and its base with the input terminal for transmitting the input signal connected by a second transistor of the first conductivity type in basic attitude, its base to ground and its emitter to the emitter of the first transistor is connected, the emitters of the first and the second transistor via a Resistor connected to the second pole of the voltage source, so that the second The transistor is blocked when the first transistor conducts current, through a one-sided AC short-circuited delay line, of which at least one Conduct the collector of the second transistor in direct current with the first pole the voltage source connects and through a transistor of the second conductivity type in basic posture, its base with the first pole of the voltage source and its Emitter is connected to the collector of the second transistor, so that at one Input signal of the first transistor conducting, the second transistor blocked and the transistor of the second conductivity type becomes conductive for as long as by locking the second transistor generated voltage jump traverse the delay path in both directions with reflection at one end Has.

The monostable pulse generator according to the invention is shown below be explained in more detail with reference to the drawing, for example, the circuit diagram of a preferred embodiment.

In the generator shown as a circuit diagram, the input terminal 10 for the triggering negative input pulse is connected to the base electrode 13 of a pnp transistor 12 via a diode 11. The collector 14 of this transistor 12 is connected to the negative pole 15 of a voltage source which emits a voltage of -6 V, for example, compared to ground potential. The transistor 12 thus operates in a collector circuit. The emitter 16 of the transistor 12 is connected via a line 17 to a resistor 18, the other end of which is connected to the positive pole 19 of a supply voltage source which, for example, emits a voltage of -a-6 V with respect to ground. The base 13 and the emitter 16 of the transistor 12 are connected to one another by a resistor 20, so that the transistor 12 is blocked in the absence of a triggering signal at the input 10.

The emitter 16 is connected to the emitter 22 of a second pnp transistor 21 for forwarding the input signal. This transistor 21 is in common base: the base 23 of this transistor is connected to ground as shown. The collector 24 of the transistor 21 is connected to a delay path 25, the signal propagation time of which determines the duration of the pulse appearing at the output of the generator. The delay line 25 is preferably designed as a coaxial cable and consists, for example, of an outer conductive cylinder 25a and a conductor 25b located centrally in this . The collector 24 of the transistor 21 is now with the right end of the conductor in the illustration. 25 b connected. The outer jacket 25 a of the delay line is connected by a line 26 to ground. The left end of the delay line in the illustration is terminated by a capacitor 27, which represents a short circuit in terms of alternating current, so that all waves or voltage jumps migrating in the delay line from right to left are reflected at the left end with phase reversal and again to that in the Return to the right end of the display. The left in the representation of the end of the central conductor 25b is further connected via a line 29 to the negative pole 15 of the first DC voltage source, so that the collector 24 is kept of the transistor 21 via the center conductor 25 b to direct current, for example, -6V.

The right end of the middle conductor 25 b of the delay line 25 in the illustration is connected to the emitter 34 of an npn transistor 33 via a line 30 and an RC combination consisting of the resistor 31 and the capacitor 32. The base 35 of this transistor 33 is connected, as shown, to the negative pole 15 of the first voltage source, that is to say is kept at a direct voltage potential of -6 V, for example. The transistor 33 is thus in the base circuit. The collector 36 of the transistor 33 is connected to ground via a resistor 37 and an inductor 38. The signal appearing at the collector 36 of the transistor 33 is amplified again by an emitter follower stage to increase the power of the pulses to be emitted. The output stage contains a pnp transistor 40 in collector circuit; its collector 41 is connected to the negative pole 15 of the first voltage source. The base 42 of the transistor 40 is connected to the collector 36 of the transistor 33 and furthermore via a resistor 46 to the connection point 19, which is held at -I-6V. The emitter 43 of the transistor 40 is connected to the output terminal 45 for picking up the generated pulses and via the emitter resistor 44 to the point 19.

To explain the mode of operation of the illustrated circuit of the monostable pulse generator, it is initially assumed that there is no pulse at input 10 appears. Under this condition, the transistor 21 is initially energized, because its base is connected to ground. In contrast, the transistor 12 is according to the connection between its emitter and base via resistor 20 is blocked. The two further transistors 33 and 40 are also before the arrival of an input signal locked. If a negative input pulse of, for example, -1 V appears opposite Ground at the input terminal 10, the diode 11 is conductive and the base 13 of the transistor 12 biased by -0.6 V with respect to ground, for example. One consequence of this is that the transistor 12 becomes conductive, which increases the voltage across the resistor 18. This increase in voltage changes the bias voltage of the basic circuit Transistor 21, so that it is blocked.

The transition of the transistor 21 to the non-conductive state interrupts the current which flows from the negative pole 15 of the supply voltage source via the line 29 and through the middle conductor 25 b of the delay path 25. This interruption, however, has a voltage drop at the right end of the conductor 25 b to the result, that is, at point 49, since the outer conductor 25a of the delay line 25 is connected to ground. This negative voltage surge arrives via the RC combination 31, 32 to the emitter 34 of the npn transistor 33, the base of which is also connected to the negative pole 15 of the voltage source, ie is kept at -6 V with respect to ground potential, for example. Due to the negative voltage at the right end of the middle conductor 25b of the delay path 25, the base 35 is now positive with respect to the emitter 34 of the transistor 33, so that the latter is converted into the conductive state.

In the circuit shown, there is a good match and therefore a favorable signal transmission from delay line 25 to transistor 33 achieved in that the transistor is in common base; the emitter-side As is well known, the input then represents a low impedance, which corresponds to the characteristic impedance corresponds approximately to the delay line. The RC combination 31, 32 fulfills here the task of the inductive characteristic of the emitter input of the transistor 33 balance during the generation of a pulse, so that the total load of the The delay path during this period is largely independent of time and ohmic will. This has the consequence that the pulse rise is comparatively steep.

The negative voltage jump appearing at the collector 36 now reaches the base 42 of the transistor 40, in which the negative signal is further amplified. The output signal appears at the emitter 43 or the connection point 45 as a negative voltage jump.

It has already been pointed out that the duration of the input signal should not affect the duration of the output signal. To prevent in the delay path 25 further voltage surges due to the termination of the input signal are triggered, the first through the delay path 25 migrating voltage jump could affect, is the collector 36 of the transistor 33 with the base 13 of the Transistor 12 connected via a diode 50. As a result, the transistor 12 is through the negative voltage on collector 36 for the duration of the output pulse held in the conductive state, even if the input signal is present Termination of the output pulse should end. One consequence of this is that the Transistor 21 remains blocked until the end of the output pulse, so that no new voltage surge is triggered in the delay line.

The voltage jump triggered by the blocking of transistor 21 at point 49, which propagates to the left in the delay line 25 is at the one in the Illustration of the left end of the delay line short-circuited in terms of alternating current 25 reflected with phase reversal, d. This means that the sign of the voltage jump reverses. After the reflection, it appears at the end on the right in the illustration the delay line 25, i. H. at point 49, a positive voltage jump, which increases the potential of the emitter 34 of the transistor 33, so that it is blocked will. In order to prevent further reflections of the wave in the delay line 25, the right end in the illustration is terminated by a diode 51. Instead of however, a resistor can also be provided for this diode.

The voltage at the collector 36 experiences a positive jump due to the blocking of the transistor 33, which represents the end of the output pulse. This voltage jump is further amplified by the transistor 40 and appears at the output terminal 45. The resistors 37 and 46 represent a voltage divider for generating the base bias of the transistor 40. The inductance 38 is used to compensate for the capacitive input impedance of the transistor 40.

It can thus be seen that the duration of the output pulse is exclusively is given by the signal propagation time in the delay line 25. There is the Possibility of designing the delay line so that its physical length is variable is, with which then the duration of the impulses that the generator can deliver can be set is. It can also be seen that through a suitable arrangement of complementary Transistors, d. H. achieved by transistors of opposite conductivity type becomes that the voltage level of the input signals and the output pulses practical is equal to. The input signal can, for example, be a pulse of -1 V while the output pulse can also have a voltage of -1 V. The resting tension at the output can be + 1 V.

It should be mentioned at this point that with a corresponding reversal of the voltages that occur, the transistors can be replaced by those of opposite conductivity. The transistors 12, 21 and 40 can thus also be designed as npn transistors if, at the same time, the transistor 33 must then be designed as a pnp transistor.

With the pulse generator shown, repetition frequencies for the output pulses of more than 10 MHz can be achieved. With an executed Pulse generator of the type described is the rise time of the leading pulse edge of the output pulse with a voltage jump of 2 V about 2.5 nanoseconds and the fall time of the trailing edge of the pulse is about 4.0 nanoseconds. The triggering impulse has an amplitude of 1 V and its duration is about 5 nanoseconds. the The power of the emitted pulses is approximately 0.1 at the voltage peak Watt. The good properties of the pulse generator, as shown, include due to the fact that one electrode of all transistors has an alternating current is due to mass.

Several deviations are possible from the circuit shown. For example, the output stage with the transistor 40 can be dispensed with if pulses of a lower power are sufficient. Furthermore, the end of the delay line on the left in the illustration can also be short-circuited in terms of direct current. In this case, the external line 25a of the delay line 25 must be connected to the point 15 of the first voltage source, while the connection 26 to ground and the line 29 are then omitted. The circuit shown has the advantage that the external line is at ground potential, which is advantageous for a number of reasons.

Claims (7)

Claims: 1 .. Monostable transistor pulse generator with a delay chain for generating pulses of predetermined duration as a result of an input signal, characterized by a first transistor (12) of a first conductivity type in a collector circuit, the collector of which is connected to one pole of a center-grounded voltage source and whose The base is connected to the input terminal (10) for transmitting the input signal, through a second transistor (21) of the first conductivity type in base circuit, whose base is connected to ground and whose emitter is connected to the emitter of the first transistor (12), the emitter of the the first and the second transistor are connected to the second pole of the voltage source via a resistor (18), so that the second transistor (21) is blocked when the first transistor (12) is carrying current, through a delay path (25) short-circuited on one side with an alternating current , of which at least one leader takes the Kollek gate of the second transistor (21) with direct current to the first pole of the voltage source (15) and connected by a transistor (33) of the second conductivity type in common base, whose base with the first pole of the voltage source and its emitter with the collector of the second transistor (21 ) is connected, so that when there is an input signal, the first transistor (12) is conductive, the second transistor (21) is blocked and the transistor (33) of the second conductivity type is conductive for as long as that caused by the blocking of the second transistor (21) The voltage jump generated has traversed the delay path in both directions with reflection at one end. 2. Generator according to claim 1, characterized characterized in that the transistor (33) has the second conductivity type third transistor (40) of the first conductivity type is connected as an emitter follower stage, the collector of this third transistor with the voltage source of the first Polarity is connected. 3. Generator according to claim 1, characterized in that the non-short-circuited end of the delay line (25) with a diode (51) is bridged. 4. Generator according to claim 1, characterized in that the base of the first transistor (12) to the collector of the transistor (33) of the second conductivity type connected via a diode (50) so that the first transistor (12) is independent from the input signal to the end of a pulse to be emitted in current-carrying State is maintained. 5. Generator according to claim 1, characterized in that the delay line (25) via a parallel connection of a resistor (31) and a capacitor (32) having the emitter of the transistor (33) of the second conductivity type connected is. 6. Generator according to claim 1, characterized in that the delay line (25) is designed as a coaxial cable. 7. Generator according to claim 2, characterized in that that the base of the third transistor (40) of the first conductivity type via a Series connection of a resistor (37) and an inductance (38) with ground connected is. References Considered: USA: Patent No. 2,564 824; "Pulse Generators", 1948, McGraw-Hill Book Co, New York, p. 121; Dillenburger, "Introduction to German Television Technology", 2nd edition, 1953, p. 210.