DE1026785B - Arrangement for delaying electrical impulses - Google Patents

Description

Pulse delay circuits are used in the field of short-term measurement and electrical Calculating devices and calculating machines and used wherever an input signal comes from an encrypted one There is a series of pulses in which the pulses occur at equal time intervals. here the task is often to postpone each such impulse to a later period of time. Pulse delay circuits of this type are z. B. Particularly useful for electronic calculating machines where the input signal is from a range of binary Pulses representing digits.

The object on which the invention is based is to create an improved arrangement to delay electrical pulses, which are simpler and more reliable than the known arrangements and is cheaper.

For an arrangement for delaying electrical pulses, the invention consists in that the signal pulse to be delayed and a periodically changing one of the pulses to be delayed not Influenced auxiliary voltage that is independent of its temporal course, preferably synchronization pulses, close a first electronic switch during the time during which the sign of the The voltage from the signal pulse and the auxiliary voltage is equal, preferably positive, to during this Time to generate a pulse, which, in order to deliver the delayed pulse, is in turn a second electronic The switch closes and remains closed until the switch is caused by the disappearance of a limiting pulse is opened. According to a further feature of the invention, the first is electronic Switch from a tube preferably working in cathode base circuit, the control grid of which is the signal pulse to be delayed and also the auxiliary voltage via separate rectifiers in the forward direction or the synchronization pulses used as auxiliary voltage are supplied. The second electronic The switch consists of a tube, preferably operating in an anode base circuit, with a grid the impulse generated at the anode of the tube of the first switch via a capacitance and a rectifier in the forward direction and also the preferably negative limiter pulses via a Resistance and a rectifier are fed in the reverse direction.

Such a pulse delay arrangement has the advantage that compared to known arrangements no strict requirements regarding impedance, waveform or constancy of the amplitude needs to put to the signal and the synchronizing pulse sources.

In the arrangement according to the invention, an arrangement for delay can be used
electrical impulses

Applicant:

IBM Germany

International office machines

Gesellschaft mbH,
Sindelfingen (Württ), Böblinger Allee 49

Claimed priority:
V. St. v. America July 30, 1951

Byron L. Havens, Closter, NJ (V. St. A.),
has been named as the inventor

without interfering with each other, the second input pulse is also received while the first input pulse is received corresponding output pulse is generated. The arrangement of the invention provides one Output pulse with an easy-to-use waveform.

Further features of the invention emerge from the following description and from the drawing. With the aid of this drawing, the invention is described below for an exemplary embodiment explained in more detail.

Fig. 1 contains the circuit diagram of a pulse delay device according to the invention;

Fig. 2 shows a graph of the time course of the approximate waveform that is exhibited result in the various parts of the circuit of FIG.

These parts are identified by the reference numbers enclosed in a circle.

In Fig. 1, the input connections to which signal pulses (curve 1) and synchronizing

+5 sierimpulse (curve 2) can be introduced, with 10 and 11 designated. In order to generate positive pulses when applying positive pulses to both inputs 10 and 11 To trigger a pulse, the rectifiers 12 and 13 are provided. These rectifiers are in between a connection point 14 and the input terminals 10 and 11 and are preferably arranged so that they allow current to pass from the external pulse source towards these input terminals offer the lowest possible resistance.

709 957/122

3 4

The connection point 14 of the two rectifiers as a result of the rectifier element 25 is not more negative 12 and 13 is through a resistor 15 with the left is as the negative potential of the terminal 28. The Control electrode 16 of an electron discharge pre-junction 35 is through the limiter potential direction 17, preferably of the double triode type, vertically (curve 4) at connection 30 via the resistor bound. The left cathode 18 of this double tube 17 5 29 and over the rectifier element 27 and the itself is due to earth. The left anode 19 of the charge of the capacitor 37 resulting therefrom device 17 is held at a negative potential to earth via an output impedance 20, consisting of a resistor 22 parallel to a This in turn causes the as catho-inductance 21, the right part of the discharge circuit connected to the positive terminal 23 is connected to the amplifier. In addition, there is a relatively low guide point between the connecting device 17 14 and the positive potential terminal 23 has a capability, so that the right cathode 40 and Resistor 24. consequently also the output terminal 42 to earth

The arrangement according to the invention also includes negative. The first half brings this state to a series network consisting of a number of rectifying time segments T 1 in the diagram of FIG.

one side at the negative potential terminal 28 It is now assumed that a synchronizing

and on the other side via a resistor 29 pulse (curve 2) is applied to the input terminal 11 at terminal 30 for the connection of a source of the. By the action of the rectifier element Limiter potential. The connection point 14 can no longer than the temporal course of this 12 The curve 4 in FIG. 2 shows the potential. The rectifier 20 is slightly more positive than the input terminal 10 Terminal elements 25, 26 and 27 are preferably arranged in the same way as the left-hand part of the discharge device 17 arranges that the current flow from terminal 28 to the remains non-conductive, and an output pulse is not Limiter potential source 30 is generated as low as possible. This state is from the second half of the Offer resistance. Time segment T1 can be seen in FIG. As well-

A series network formed from a number of impedance elements can be a little bit through the presence of a positive and finally the capacitor 31 and the resistance signal pulse (curve 1) at the input connection 10 32. Between the left only the left part of the discharge device is conductive between the left anode 19 of the discharge device 17 and denega- to be switched to an output pulse to generate potential terminal 33. The gene falls, as shown in the first half of the time segment connection point 34 between the elements 31 and 30 T2 in FIG.

32 with the connection point between the equals but if positive impulses are sent simultaneously to the

judge elements 25 and 26 together. Input terminals 10 and 11 occur like the

The connection point 35 between the rectifying second half of the time segment Γ 2 in Fig. 2 shows ter elements 26 and 27 can be used as an output terminal then the connection point 14 is positive and the the delay circuit itself. One of 35 left part of the discharge device 17 conductive, the resistor 36 and the capacitor 37 exist - This creates a negative pulse (curve 3) of the series network is between the right control and the left anode 19, which in turn discharges the electrode 38 of the discharge device 17 and ground capacitor 31 causes, while the potential of the switched. The connection between the impedance junction point 34 is essentially unchanged elements 36 and 37 is at the connection point 35 40 remains. As soon as the synchronization pulse (curve 2) connected. The right anode 39 of the discharge end becomes the left part of the gas discharge device 17 has connection to the positive terminal 23. Device 17 blocked, the voltage at the left anode The right cathode 40 of the tube 17 is above a 19 (curve 3) rises due to the inductor impedance element or a resistor 41 at the negativity 21 in the anode circuit to a voltage that ven potential connection 33. The output terminal 42 is 45 higher than that when the anode current is blocked. Since the connected to the cathode 40. The resistors 15 inductance 21 along with inevitable and 36 serve to prevent undesired intrinsic switching capacitances and the anode resistance 22 Vibrations. forms a damped oscillation circuit, so takes

All of the voltage at the anode 19 for the pulse delay circuit very quickly (ie, according to FIG. 1, the supply voltages required after one oscillation) can again correspond to their quiescent value from the positive and negative potential sources. The positive edge of this oscillation will be taken over, which have a common grounded capacitor 31 and rectifier element 26 connection. The non-grounded connection of the connection point 35 in the form of a positive positive potential source is effective with the terminal 23, the pulse by which the capacitor 37, non-grounded connection of the negative potential source 55 is charged. The right part of the discharge with the terminal 33 and the connection 28 with a device 17 is made more conductive in this way, essentially special tapping of the negative potential source, so that a positive output is connected, pulse (curve 5) at the cathode 40 and the output For the use of the arrangement, the input connection 42 is first created. As the time period T 3 assumes that no signal and sync pulses are shown at 60 of FIG. 2, this state remains until the input terminals 10 and 11 appear. Under the next limiter potential pulse (curve 4) in these circumstances, these connections are applied to time segment T 4.

Earth sufficiently negative that the left side of the

Double tube 17 is non-conductive. Thus, the left way of the arrangement according to the invention is evident Anode 19 essentially the potential of the positive 65 that a potential connection occurs in a certain period of time 23, and the capacitor 31 becomes the input pulse generating an output result the difference between the positive pulse in the following period. Potential of the terminal 23 and the negative potential. It also shows that an input pulse of the terminal 33 is charged during the connection in a period of time simultaneously with the generation connection point 34 is held at a potential that can be received 70 of an output pulse,

Claims (1)

5 6 which the auxiliary voltage (2) resp. cut received input pulse corresponds to the synchronization used as auxiliary voltage without mutual interference taking place. pulses (2) are supplied. For a particular embodiment of the invention 3. Arrangement according to claims 1 and 2, application, in which the time intervals a microsecond 5 characterized in that the second electro-long and in which each signal pulse is a minor switch from a preferably in anode at least the last third of this period of time is a single-base circuit tube (17, right), If it has proven to be particularly advantageous, the grid (38) of which stands at the anode of the tube Select the circuit elements in the following way- (17, left) resulting impulse (3) over the capals and to be measured: io city (31) and rectifier (26) in the pass-through direction Resistors 15 and 36 330 ohms Jf ¹ S ^and also the preferably negative ones Resistors 22 and 41 8,200 Ohm limiter impulses (4) via the resistor (29) Resistance 24 82 000 Ohm " ^{nd the rectifier} C ²⁷ ) ⁱⁿ Spernchtung. Resistance 29 1200 ohms. - _u ^ - * * Resistor 32 180 000 Ohm ¹ S ⁴ · Arrangement according to claims 1 to 3, there- Capacitor 31 68 micromicrof arad? U.rch marked that between the grid Condenser 37 22 micromicrofarads ( ³⁸ ) ^d ^ ^tubes ^ ¹ J ' ^right ) ^{and ground eme Ka} P ^a ~ Inductance 21 0.75 Millihenry quote (37) is arranged Rectifiers 12, 13, 25, 26, 27 Type IN 45, 5. Arrangement according to Claim 4, characterized in that Discharge device 17 ... Type 12 AV 7 ²⁰ indicates that the introduced limiting Potential connection 23 +150 volts ^{in the pulse} ( ⁴ ) ^em specific fixed phase relationship Potential connection 28 - 30 volts ⁿ \ ^{s to the} f delaying signal pulses (1) Potential connection 33 - 82 volts ^or ff ^de , have ⁿ synchronization pulses. 6. Arrangement according to claims 2 to 5, there- 25 characterized in that the anode voltage Claims: (J ₆₁ - directly from the signal pulse (1) and from the 1st arrangement for delaying electrical Im- Synchronisierimpuls (2) controlled tube (17) pulse, characterized in that the delayed via a reactance (20), in particular gladly Signal pulse (1) and a periodically changing resistor (22) via an induction coil (21) with a parallel changing resistor (22) that is not switched by the pulses to be delayed,
influenced and un- 7. Arrangement according to claims 3 to 6, there dependent auxiliary voltage, preferably synchro- characterized in that the from the Signalimnisierimpulse (2), a first electronic pulse (1) directly controlled discharge switch during the Close time, during the direction and the output of the delayed the sign of the voltage from the signal pulse 35 pulse (5) controlled discharge device (1) and the auxiliary voltage (2) equal, preferably form a double triode. wise positive, is to during this time an 8. arrangement according to claims 1 to 7, pulse (3) to generate the delayed character by a pulse key combination pulse (5) to deliver, in turn, a second nation of the signal pulses to be delayed The electronic switch closes and remains in the binary number system for as long. holds closed until the switch is broken by the 9. Arrangement according to claims 1 to 8 a limiting pulse (4) geöff- characterized in that the Synchronisiernet will. pulse frequency is greater than the frequency of the to 2. Arrangement according to claim 1, characterized by delayed pulses,
draws that the first electronic switch from 45 One of the publications preferably considered in a cathode base circuit: working tube (17, left), whose tax Swiss patent specification No. 221753, grid (16) of the signal pulse to be delayed (1) 236 114,270 410; and also via separate rectifiers (12,13) U.S. Patent No. 2,512,152. 1 sheet of drawings 1 709 957/122 3. 58