DE962442C - Arrangement for converting from an electrical memory in preferably irregular sequence supplied, rapidly successive pulses into a number of electrical pulses proportional to the stored number of pulses or to a number of electrical pulses that corresponds to this electrical quantity - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

ISSUED APRIL 25, 1957

GERMAN PATENT OFFICE PATENT LETTERING

CLASS 21a ¹ GROUP 36 INTERNAT. CLASS H 03k -

E 8t 55 VIII a 12i a * -

Robert Favre, Lausanne (Switzerland)

has been named as the inventor

Ebauches S. A., Neuchätel (Switzerland)

Arrangement for converting an electrical storage device into preferably irregular sequence supplied, rapidly successive pulses in one of the stored number of pulses or one of these corresponding electrical quantity proportional number of electrical impulses

Patented in the territory of the Federal Republic of Germany on March 23, 1954 Patent application published October 31, 1956

Grant of patent announced on April 11, 1957 The priority of the application in Switzerland of April 1, 1953 has been claimed

The present invention relates to an arrangement for converting an electrical storage device in a preferably irregular sequence supplied, racing successive, pulses S in one of the stored number of pulses or one this corresponding electrical, size proportional Number of electrical impulses at which depending on the charge status of the storage tank pulse generating electrical circuit is made unstable.

Such arrangements for pulse counting are already known per se. With these, the incoming Impulses z. B. as. electrical charge stored on a capacitor, and the capacitor is z. B. suddenly discharged at every tenth pulse while passing on a pulse. The discharge takes place in a known arrangement by a blocking oscillator, which when a certain state of charge of the capacitor is reached, the capacitor becomes unstable

discharges and passes on an output pulse. At Place of the blocking oscillator, it was also suggested to use a univibrator, which basically has the same function! exercises like the blocking transducer. There are also more complicated multi-tube circuits for pulse counting after the Storage principle known, in which the discharge of the capacitor with a certain delay takes place, which is to prevent that ίο the capacitor is discharged before his Charge has controlled the delivery of an output pulse in the prescribed manner.

All of these known. Orders are so far has a disadvantage that the capacitor takes a certain time to discharge the latter arrangement even with a certain. Delay occurs, so it · very well it is possible that a new input pulse arrives while the capacitor is discharging, which is then of course also immediately discharged and is therefore lost for counting. These There is a particular danger when the input impulses arrive irregularly, so not with a minimum time interval, which z. B. at a5 the measurement of pulses caused by cosmic rays or the like, is the case. Furthermore, these known arrangements are not able at the end of the measurement in the capacitor remaining charges that are not sufficient to trigger a new counting pulse., to count, and. special counting devices must be provided for this purpose.

These disadvantages of known circuits are now avoided by the arrangement according to the present invention, in that means are provided for the stored electrical charge regardless of the state of the unstable. Circle steadily at least approximately linearly and to let a circle which can oscillate with a constant, predetermined repetition frequency, for example a multivibrator, become unstable during such a time, depending on the size of the stored electrical charge / time, that it has a number proportional to the stored electrical charge of, electrical impulses emits in regular succession. In contrast to the above-mentioned known circuits, the electrical storage device, e.g. Regardless of the state of the unstable circuit continuously at least approximately linearly discharged as a capacitor, \ ^r orliegendeir according to the invention, and therefore, the charge of the memory can at any time and in particular independently of the instantaneous! State of the unstable circuit can be increased by a newly arriving input pulse in order to extend the influence of the memory on the unstable circuit in such a way that each incoming input pulse is taken into account in the number of pulses emitted by the same. A loss of input impulses is therefore excluded. Furthermore, the arrangement according to the invention is able to select the input pulses completely without the need for special means.

In connection with electronic counters, the invention offers further significant advantages. The resolving power of an electronic. Counter in which the incident, to counting electrical pulses are fed to the input circuits of a frequency divider by the response speed of this input circuit limited. Therefore, if there are successive pulses within the response time follow the input circle, this will behave as if; only the first impulse arrived would be so. that the second pulse is not counted and thus; the measurement result would be falsified. Thanks to the invention, such a loss of pulses can now be avoided without the Response speed of the input circuit of the electronic counter and the frequency divider increase yourself. According to the invention this goal is achieved in that means are provided from every incoming pulse applied to the input circuit, and from at least one further, during 'the response time of the input circuit mentioned. Impulse an impulse derive, which brings this, input circuit as an extended input pulse, as a multivibrator to work, and. to deliver a number of pulses, which is equal to the number of pulses occurring during the response time.

In this way, randomly distributed incoming impulses, their mean frequency is equal to or lower than the frequency of the input circuit working as a multivibrator, without Losses are counted.

The invention is described below with reference to two exemplary circuits for increasing the resolving power of frequency dividers explained in more detail.

Fig. Ι shows a circuit in which a binary input circuit is provided which belongs to the frequency divider while

2 shows a circuit in which a so-called "flip-flop" input circuit is cascaded is switched with a normal, for example already existing · frequency divider.

First of all, the mode of operation of the binary. Input circuit of the frequency divider. · .. This circuit has two electron tubes. T 1 and T 2, of which at each moment one is conductive and the other is michitleitendi. This mode of operation is obtained by connecting the control grids of these tubes through, voltage dividerri, rg-2. or ra, rgi are polarized, via which a cross-grid-anode coupling of the tubes takes place and which are connected to the anode V2 of a further electron tube Tc . The cathode of the tube Tc is connected to the line V3 carrying a negative potential. The anodes of the tubes T 1 and T 2 are connected to an anode voltage source Vi via load resistors, respectively R 2. The voltage dividers mentioned are dimensioned in such a way that the control grid potential of one tube is always below the

Blocking initial is negative, if that other tube is conductive, and then slightly · above cathode potential lies where it cannot rise any further as a result of the grid current if the other tube is non-conductive is.

For the purpose of correct transmission of the rapid voltage changes! on the anodes of the tubes, on the grids of the other tubes, are between the anode of each tube and the grid of the

ίο each other tube coupling condensers Ci or C 2 provided :. The binary circle can assume two different stable states in which one tube is conductive and the other non-conductive or vice versa.

If a positive voltage surge of sufficient voltage occurs at the anode V2 of the tube Tc , the binary circuit changes from one to the other stable state, ie the non-conductive tube becomes conductive, and. The conductive tube becomes non-conductive as a result of the negative voltage surge, which is applied to its grid from the anode of the previously unconnected tube via the coupling capacitor.

However, if the voltage increase occurring at the anode V 2 of the tube Tc continues for a longer period of time, the grid voltage in the tube that has just become non-conductive as described above will again rise above the blocking potential aiir Way a renewed overturning, the circuit takes place, etc. The binary circuit will now work as a multivibrator as long as the potential increase at the anode V2 of the tube Tc continues.

The control grid §-3 of the tube Tc is via a diode or a rectifier d 1 and. a: coupling capacitor C 3 connected to the anode of a preamplifier tube T. The grid potential of the tube Tc is kept above the cathode potential in the idle state of the circuit by the voltage divider formed from the high-resistance rg2 and the rectifiers or diodes, d 1 and d2. Between the grid and the cathode, the. A storage condenser at or C is arranged in tube Tc.

The incoming pulses to be counted are sent to the control grid of the preamplifier tube T. placed, which is biased under blocking potential in the idle state. When a positive pulse arrives, the control grid of the tube T becomes more positive, so that this tube becomes temporarily conductive. The negative voltage surge occurring at the anode of the tube Γ is passed through the coupling capacitor C 3 and the, rectifier or diode d 1 to the storage capacitor C and. transferred to the grid g 3 of the tube Tc . In the process, the storage capacitor C is discharged and is then slowly recharged via the resistor rg 3 from the positive voltage source · Vi ratio. The positive voltage surge occurring at the anode of the tube T at the end of the pulse is discharged via the diode d2 without influencing the grid g "3 of the tube Tc and the storage capacitor C.

Each incoming pulse will cause a voltage drop at the grid of the tube Tc , whereby the voltage drop in this tube and thus the potential at the anode V2 increases. The binary circle with the tubes, Ti and T 2 becomes unstable and changes to the other state. The coupling capacitor C 3, the internal resistance of the diode d1, the storage capacitor C and the charging resistor rg3 are dimensioned so that when a single one is applied. Pulse to the control grid of the preamplifier tube T, the negative pulse transmitted to the capacitor C and to the grid g 3 of the tube Tc lasts and is of such a voltage that the binary. Circle his: state changes once.

If, however, another pulse is applied to the grid of the tube T> before the binary circuit has returned to its stable state, a second unit charge is stored in the capacitor C , which is practically the same as the charge stored at the arrival of the first pulse is. Thereby the negative pulse applied to the grid g 3 of the tube Tc is amplified and. Maintained so long that the binary circle, which is still in the unstable working area, tips over again, namely again in the state originally assumed.

If three pulses in rapid succession are applied to the control grid of the input tube T during the response time of the binary circuit, then in the above-described. Way, three unit charges are stored in the capacitor C. Thanks to the high voltage of the voltage source Vi and the high value of the resistor rg 3, the discharge of the storage capacitor is approximately linear, so that the duration of the negative voltage surge applied to the grid of the tube Tc, for which the binary circuit becomes unstable, is practically proportional to the Number of pulses which were applied to the control grid of the tube T within the response time of this circuit. It is therefore possible by suitable dimensioning of all parts to choose the duration of the instability of the binary circuit in such a way that the number of pulses emitted by this circuit in an oscillating state is equal to the number of pulses or unit charges in the storage capacitor C. are stored. In this way, it is always possible to convert a sequence of randomly distributed pulses, the mean repetition frequency of which is equal to or less than the frequency of the binary circle operating as a multivibrator, into a sequence of pulses. Repetition frequency is at most equal to the frequency of the multivibrator.

The structure and mode of operation of the circuit shown in FIG. 2 are quite similar to those of the circuit according to FIG. 1, with the only difference, that instead of the symmetrical, binary circle one only one stable.

State, exhibiting flip-flop circuit is provided. The preamplifier tube, the coupling capacitor C 3 and the diode d 2 are not shown in FIG. 2 for the sake of simplicity. So this flip-flop circle is different from. diena symmetric binary. Circle of Fig. Ι in that it has only one stable state in the idle state of the circuit, in which the grid of the tube T ι is on cathode potential and ίο thus the tube T ι is conductive, and where the grid of the tube Γ 2 is below the Speirrpotentials and this tube is therefore non-conductive. If a positive voltage surge occurs at the anode V2 of the tube Tc, the tube Γ 2 becomes conductive, whereas the voltage at the grid of the tube T1 is caused by the negative voltage surge, which is generated via the coupling capacitor C 2 from the anode of the tube T 2 to the same is transmitted, drops below the blocking potential and the tube T 1 becomes non-conductive. After a certain time, within which the flip-flop circuit is in a metastable state, the grid potential of the tube T 1 will rise again to the cathode potential, whereby the tube T 1 is again conductive and the tube T 2 is non-conductive.

If, on the other hand, a constant voltage rise occurs at the anode of the tube Tc , the flip-flop circuit becomes permanent, unstable and oscillates like a single. Multivibrator as long as the voltage rise at the anode V2 of the tube Tc continues. The circuit is again dimensioned so that when a single one arrives. Pulse the flip-flop circuit becomes unstable and emits a pulse on the line connected to the input of a counter or frequency divider!). If several rapidly successive pulses arrive during the response time of the flip-flop circuit, these pulses are stored as unit charges in the capacitor C in the manner already described, so that the voltage drop on the grid g 3 of the tube Tc lasts as long as is necessary to let the flip-flop circuit become unstable for such a period that it, working as a multivibrator, emits a number of pulses on line D corresponding to the number of pulses received.

The circuit shown in Fig. 2 is primarily for use with an existing one Counter or frequency divider determines the resolution of which, in and of itself, is insufficient would to the rapidly successiveu impulses of a randomly distributed. Pulse train to differentiate.

The charging resistor rg 3 of the storage capacitor ate rs C could also be connected directly to the cathode of the tube T _c , in which case, however, the linearity of the capacitor discharge would be impaired compared to the circuit shown.

Claims (9)

PATENT CLAIMS: i. Arrangement for converting an electrical storage device into a preferably irregular one Follow supplied, rapidly successive pulses into one of the stored ones Number of pulses or a number proportional to one of these corresponding electrical quantities electrical impulses, in which, depending on the state of charge of the storage, an impulse-generating electrical circuit is made unstable, characterized in that Means are provided for the stored electrical charge regardless of the state of the unstable. Circle steadily at least approximately linearly and to a circuit that can oscillate with a constant, predetermined repetition frequency, for example a. Multivibrator, during such, of. the size of the stored electrical Charge dependent. Time to let it become unstable that it is one of the stored, electrical Charge emits a proportional number of electrical impulses in a regular sequence. 2. Arrangement according to claim 1, wherein the storage means consists of a capacitor, characterized in that said oscillatable circle in dependence on the decaying. Capacitor voltage is made unstable. 3. Arrangement according to claim 2, for counting, pulses, in the known per se Way a certain number of. Pulses, for example ten, in a capacitor stored and then, counting every tenth pulse the capacitor suddenly is discharged, characterized in that depending on the decaying. tension of the discharging capacitor, the oscillating circuit kept unstable for so long until it has a number of pulses equal to the number of remaining, stored pulses has submitted. 4. Arrangement according to claim '1 or 2, used to increase the resolving power of electronic counters or frequency dividers for irregularly incident electrical impulses, which are capable of oscillating Input circuit of the aforementioned electronic counter or frequency divider supplied are, characterized in that means are provided in order to get out of each incoming! pulse applied to the input circuit · and. from at least one further, a pulse applied during the response time of said input circuit derive, dier this. Input circle as an extended input pulse than Multivibrator to work, and to deliver a number of pulses, equal to the number of the pulses occurring during the response time. 5. Arrangement according to. Claim 4, wherein the storage means is a capacitor, thereby characterized in that the capacitor has a high resistance. Resistance from one Voltage source © high voltage is charged or discharged. 6. Arrangement according to claim 4 or 5, characterized in that said oscillatable input circuit designed as a first binary stage of a frequency divider is that in a non-oscillating state it takes on two stable switching states can, and that the incident, possibly to be extended, pulses to the control grid an electron tube, the anode of which with the grid resistances i the binary Stage is connected and its cathode potential is below the cathode potential of the Tubes, the binary circle lies. 7. Arrangement according to claim 4 or 5, characterized in that said vibratory input circuit such as FHp-FIop-Kre: s. is trained to be in such a non-vibrating state, a stable one and assume a metastable switching state can that this Flio flop circle with a frequency divider is connected in cascade and that the possibly · to be extended incident impulses. the control grid of an electron tube are applied, its anode with the grid series resistor of the tube, which is blocked when the flip-flop circuit is idle this circle is connected and its cathode potential is below the cathode potential of the tubes of the flip-flop circuit. 8. Arrangement according to claim 6 or 7, characterized in that the incident pulses are fed as negative pulses to the grid of said electron tube via a blocking cell, preferably a diode {d 1), and that the storage capacitor is connected to the grid of this electron tube, The input circuit of the electron tube is dimensioned in such a way that, if a certain number of incident pulses occurs during the response time of the oscillatable circuit, a pulse is generated corresponding to this number compared to the first pulse incident within the response time. 9. Arrangement according to one of the preceding claims for the reception of positive input pulses, characterized in that the input pulses to the control grid a normally blocked input tube, which can be applied by the pulses is unlocked, and that the storage capacitor the negative pulses occurring at the anode of this input tube Coupling agents are supplied. Considered publications:
Progress of Radiotechnik, 12, 1950/51, supplement volume, pp. 69 to 71;
British Patent No. 633 099. For this purpose, 1 sheet of drawings © 609 650/163 10.56 (609 865 4.57)