BE491567A - - Google Patents

Description

       

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  Electronic counter
The subject of the invention is an electronic counter comprising several tilting circuits connected to one another so as to form a chain, each of these tilting circuits comprising a pair of electronic control grid tubes coupled in a cross so that one of these tubes change from state to state

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 conductive stable state to a non-conductive stable state and vice versa and that the other passes simultaneously from a non-conductive stable state to a conductive stable state under the effect of electric pulses.

   It has particularly, but not exclusively, an electronic counter of binary structure, comprising a set of tilting circuits interconnected in such a way that this counter is capable of counting according to the decimal system. Each of said rocking circuits took alternately one and the other of two stable states under the effect of input pulses. One of these stable states will be designated below as the EN state, a rocking circuit being in this state when its rear tube is non-conductive, its left tube being conductive. The other stable state, in which the right tube of a rocking circuit is conductive and its left tube is non-conductive, will be designated as the OFF state below.



   Means are known for transforming a binary structure counter into an aecad counter. Generally, these means comprise at least one circuit serving to return pulses, from a switching circuit to a higher order and to apply them to a circuit, switching to a lower order, in a set of such. tilting circuits.



  This circuit comprises at least one resistor and one capacitor and enables the counter to provide one output pulse for each group of ten input pulses received. The use of such resistance-capacitance feedback circuits to convert a binary counter to a decade counter has drawbacks. Indeed, these return circuits have frequency discrimination characteristics such as the maximum frequency at which

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 pulses can be supplied to this meter to make it work satisfactorily is limited. Thus, such counters cannot operate at very high speed.



   Another defect of known counters lies in the shielding or insufficient separation of their different stages. In addition, the use of non-inductive anode load resistors of relatively large dimensions has the effect of short-circuiting, for very high frequencies, the control gates of the tubes included in the tilting circuits, when these circuits are controlled by their grids.

   This peculiarity results in an adverse reaction to one circuit switching to the other and an appreciable load of the lower orare switching circuit. Particularly when the tilting circuits of such a meter are coupled to each other without the intermediary of the electronic coupling or separation tubes, the tilting circuit which controls the next circuit is heavily loaded and the speed is high. The maximum operating speed of the meter is thereby reduced and becomes appreciably lower than the maximum operating speed which can be reduced for the rocking circuits of which it is composed.



   The invention aims to provide a counter capable of counting input pulses at a speed close to the speed at which the separate rocking circuits which compose it are capable of operating. For this purpose, the first aes rocking circuits of the electronic meter object of the invention is that having the highest speed of operation, the second having a speed pro: re operation higher than the circuits

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   next tilting.



   The appended drawing represents, by way of examples, two embodiments of the electronic counter which is the subject of the invention.



   Fig. 1 is the electrical diagram of the first embodiment.



   Fig. 2 and fig. 2a taken together constitute the electrical diagram of the second embodiment and FIG. 3 is a table illustrating the operation of this second embodiment.



   As far as possible, the same reference signs have been used to designate corresponding elements of the two embodiments.



   The electronic decade counter, the electrical diagram of which is shown in fig. 1 comprises four rocking circuits designated respectively by A, B, C and D.



  It also includes coupling or separation electron tube circuits denoted by E and F respectively and a blocking electron tube circuit signed by G. The four rocking circuits and the tube circuits E, F and G are separated by vertical dotted lines. The tilting circuits A, B, C and D each comprise two control grid tubes designated respectively by A1 and A2, B1 and B2, C1 and C2 and Dl and D2. These tubes are shown as tetrodes, the rocking circuit A using two tubes of type 807 and the rocking circuits B, C and D each using two tubes of type 6L6.



   Each rocking circuit provides one pulse that output for each group of two input pulses that it

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 receives, and this output pulse actuates the next higher order rocking circuit. Since the rocking circuit A must operate at a higher speed than the rocking circuit B, and the latter also at a higher speed than the rocking circuit C, the latter having to operate at the same speed as the rocking circuit D, it is obvious that the use of tubes having the same characteristics for the rocking circuits A, B, C and D would limit the maximum operating speed of the meter to that of the rocking circuit A.

   The rocking circuits B, C and D have, in the order of enumeration, decreasing effects on the speed limit of operation of the meter. for this reason, only the rocking circuits A, B and C are coupled together via separation tubes. Tubes of the type 807 are used in the tilting circuit A because the characteristics of this type of tube are better suited to operation at the relatively high frequencies demanded of this tilting circuit.

   To further increase the maximum operating speed of the counter, the actuation pulses are applied to the anode circuits of the tilting circuits A and B and any interaction between the tilting circuits A and B on the one hand and between these first two tilting circuits and the tilting circuits C and D on the other hand by means of the aforementioned separator tube circuits. These latter features will be described in detail later.



   Each of the rocking circuits A to D has two bible states designated respectively by EN and by OUT, the respective states of each of the two tubes of each banculane circuit: as described above. On the

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 diagram, the rocking circuits are represented in their chosen initial state, all these circuits being in the OFF state and the point appearing on the right of the right tube of each of the rocking circuits indicates that this right tube is conductive. The point appearing to the right of each of the tubes El and FI indicates that each of these tubes is conductive when the rocking circuits A, B, C and D are in the OFF state.



   In the description which follows, the values of the various voltages applied, the resistances and the capacitors used will be indicated. These values are given only by way of example and with the aim of illustrating and providing a better understanding of the operation of the counters described. They represent, together with the types of tubes mentioned, a set of favorable values for the operation of these meters. The operation of the rocking circuit A will be described in detail, the operation of each of the rocking circuits B, C and D being identical to that of the rocking circuit A, except as regards certain peculiarities which will be highlighted in the course of the discussion. description.



   The cathodes 10 of the tubes A1 and A2 are directly connected to a line 11 of zero potential. The anode 12 of the tube A1 is connected to a line 13 at + 225 V via a resistor 14 for suppressing parasitic oscillations and ae resistors 15 and 16 arranged in series.



  The anode 12 of tube A2 is likewise connected to line 13 at + 225 V via a suppression resistor 17 and a resistor 18 connected in series with resistor 16. The screen grids of the tubes Al and A2 are respec-

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 tively connected to line 13 at + 225 V through resistors 31 and 32 and a connection 34. Resistors 14 and 17 are 47 ohms each and resistors 15, 16, 18, 31 and 32 ue 1000 ohms each.



   A connection 19 connected to the common point of resistors 17 and 18, on the other hand, ends at the upper end of a voltage divider formed by resistors 21 and 22 of 21,000 ohms each. The lower end of this voltage divider is connected to a -100 V bias line 22. A 215 picrofarad (pF) capacitor 23 shunts resistor 20. An adjustable neutralization capacitor 106, 13 pF, is connected between the upper end of the voltage divider 20,21 and the screen grid of the tube Al. The control grid of the tube Al is connected to the common point of the resistors 20 and 21 via the one resistor 24 for suppressing oscillations noise does not have a value of 47 ohms.



   Similarly, a connection 25 is connected on the one hand by a common point to resistors 14 and 15 and on the other hand to the upper end of a voltage divider consisting of resistors 26 and 27 of 21,000 ohms each. .



  The lower end of this voltage divider is connected to a bias suppression line 30 which is normally brought to a potential of -100 V. A 215 pF capacitor 28 bypasses resistor 26 and an adjustable capacitor of. neutralization 107, of 13 pF, is pinned between the upper end at voltage divider 26,27 and the screen grid at tube A2. The control grid for this A2 tube is connected. common to these resistors 26 and 27 through a 47 ohm suppression resistor 29. This

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   The same common point of the resistors 26 and 27 is connected to the control grid to the tube El of the circuit E, to control the conductance of this tube El in a determined cyclic manner, as described below.



   The counter comprises an input terminal 40 to which pulses to be counted are applied.



   These pulses are negative voltage pulses presenting a characteristic or a form favorable for the actuation of the rocking circuit A, when they are applied to the terminal 40. This terminal is connected to a point 42, common to the resistors. 16, 15 and 18, via a connection 41: pulses are thus applied to the common circuit, formed by resistor 16, to the anodes of the tubes A1 and A2 of this rocking circuit. It should be noted that the constants of the rocking circuits are chosen so that positive pulses of amplitude equal to those of the negative pulses to be counted cannot actuate these rocking circuits.



   In the initial state chosen at the meter, each of the rocking circuits is OFF, the right tube ae each of these circuits being conductive as indicated by the point and its left tube ae being non-conductive. Each of these right tubes has its control grid connected to a polarization suppression line 30. A polarization suppression switch CBS is provided to restore the tilting circuits to their chosen initial state. This replacement is carried out by opening and then closing this CBS switch.

   When the CBS switch is open, the grid potential of each of the right-hand tubes increases slightly above zero potential, thus meeting these

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 conductive tubes, which has the effect of reducing their anode potentials and consequently the grid potentials of the left tubes, making the latter tubes non-conveying. The anode of each of the left ae tubes is thus brought to a high potential, maintaining the aroite tubes in their conductive state, even after closing the CBS switch.



   When a negative pulse is applied to terminal 40, it decreases the potential of the anodes of the two tubes A1 and A2. This decrease in potential is transmitted to the control gates of these tubes A1 and A2 via the capacitors 23 and 28. The decrease in momentum from the control grid to the tube A1 has no effect. direct effect on this tube, since its gate potential is already lower than its cut-off potential and it is already non-conductive.

   The decrease in potential from the control grid to the conductor tube A2 renders this tube non-conductive, which leads to an increase in its anode potential. This increase is applied to the grid which controls the Al tube through a circuit comprising the connection 19, the capacitor 23, the resistor 20 and the resistor 24, so that this Al tube begins to conduct. The current flowing through tube A1 results in a decrease in its anode potential and this decrease in potential is transmitted to the control grid of tube A2 through a circuit comprising connection 25, capacitor 28, resistor 26 and resistor 29.

   According to a well-known cumulative effect, the tube A2 is kept non-conductive until the moment when the next negative pulse is applied to 1 terminal 40. Thus, the first negative pulse

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 switches the rocking circuit A, from its OFF state to its ON state.



   When the rocking circuit A thus passes from its OFF state to its EN state, a negative voltage is transmitted to the control gate of the tube E1 through the intermediary of the connection 25, connected to the anode circuit of the tube A1 and of the capacitor 28. This grid is thus polarized below the cut-off potential at the tube E1 which changes from its conveying state, as shown, to a non-conductive state.



   When a second negative pulse is applied to terminal 40, it brings the control gate of tube A1 to a potential lower than its cut-off potential and thus changes this tube from its conductive state to a non-conductive state. , by the cumulative effect, the tube A2 becomes conductive. The anode potential of tube A1 increases and this increase is transmitted to the control grid of tube A2 to maintain it in its conductive state until the next negative pulse is applied to terminal 40. Thus, , the second negative pulse switches the rocking circuit A, from its ON state to its OFF state.

   When the tilting circuit A is in the OFF state, the control grid of the tube A2 is brought to a polarization potential close to zero, as is the control grid of the El tube which is directly connected to the circuit. of the A2 tube control grid. The tube E1 is consequently rnuu conductive. When this tube passes from a non-conductive state to a conductive state, its anode potential decreases and this decrease in potential is transmitted to the common point of the resistors 53, 15 and 18 of the anoua circuit of a rocking circuit B, by through a

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 100 pF capacitor 44.

   The rocking circuit B is thus switched, from one of its states to the other.



   The switching circuits A and B are therefore controlled by negative pulses applied to their circuits! anode, which makes it possible to increase their non-operating speeds, and thereby the operating speed of the meter, and to operate the latter at a speed greater than that which would be admissible if the cir - tilting tubes A and B were controlled by capacitive coupling of their control gates, as is the case for the tilting circuit C. The cathode of the tube El is connected to 1 line 11 of zero potential and its anode is connected to line 33 at + 150 V via a resistor 45 of 1000 ohms.

   The screen grid of this same tube is connected to line 33 at + 150 V by means of a resistor 49 of 2700 ohms and to the control grid of tube D1 by means of a connection 47 and of a capacitor 48 of 40 pF.



   The tube El is conductive when the tilting circuit A is in its OFF state and it is non-conductive when this tilting circuit A is in its EN state. The positive pulse applied to the control grid at tube E1, from the anode circuit of tube A1, when rocker circuit A changes from its ON state to its OFF state, is generally effective in making the tube E1 conductor and to make it transmit, from its anode, and via the capacitor 44, a negative pulse to the common point of resistors 53, 15 and 18 of these anode circuits of the tubes of the rocking circuit B, from so as to modify the stable state of this rocking circuit.

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  The use of tube E1 as shown, to couple the rocking circuits A and B together, decreases the load applied to the rocking circuit A and prevents any capacitive interaction between these rocking circuits. This arrangement thus makes it possible to operate the counter at a higher speed than if these tilting circuits were directly coupled to one another. It has been observed that by directly coupling the circuit of the control grid of tube A2 to the control grid of tube E1, the rocking circuit A is less loaded than if it were directly coupled to the rocking circuits B and D.



   A blocking tube G1 that comprises the blocking circuit G has its anode directly connected to the anode of the tube El and its cathode to the line 11 of zero potential. The screen grid ae this tube Gl is connected to line 13 at + 225 V by means of a resistor 56 of 1000 ohms and its control grid is connected to the anode of tube D2 of rocker circuit D by through resistors 54a and 99. These resistances are respectively 1200 and 470,000 ohms and they are connected in series as shown. Their common point is coupled to the anode of tube Dl to the rocking circuit D via a 10 pF capacitor 100 and to line 22 at - 100 V via a resistor 102 of 470. . 000 ohms.



   The elements of flip-flop circuits B, C and D are similar to the corresponding elements of flip-flop A. In flip-flop B, a capacitor 51 shunting resistor 20 has a capacitance of 250 pF, as does a capacitor. 52 bypassing resistor 26. The capacitors 51 and 52 of the rocking circuits C and D are

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 of the same value as those of the rocking circuit B. A separation and coupling tube FI of the coupling circuit F prevents any harmful interaction between the rocking circuits B and C and decreases the load on the rocking circuit B, which makes it possible to increase the operating speed of these two tilting circuits to a speed close to that at which each of them could operate if they were not connected to any other circuit.

   This arrangement therefore eliminates any limitation on the speed of operation of the meter, such limitation being inevitable in meters using tilting circuits coupled directly to one another.



   When the tube B1 to the rocker circuit B becomes non-conductive, that is to say when the rocker circuit B is switched to its OFF state, a positive voltage is transmitted to the control gate of the tube FI, to from the anode of the tube B1 and through the connection 25 and to the capacitor 52. The tube FI is thus re-conducting and it is conducting when the toggle circuit B is in its OFF state. Each time the tube FI becomes a conductor, it transmits, from the midpoint 55a of its load resistance anode and via the connection 60 and the capacitors 48 and 61, a negative pulse to the rocking circuit. C to switch the stable state of this rocking circuit.



   The anode of the tube FI is connected to line 33 at + 150 V via two resistors 55 of 500 ohms each, its screen grid is connected to the same line 33 via a resistor 56 of 1000 ohms, more

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 Indeed, this resistor 56 does not fulfill the same role as the resistor 49 which must have a sufficient value so that the potential difference appearing at its terminals can modify the stable state of the tilting circuit D. This way of switching the tilting circuit D and to return the counter to its chosen initial state will be described later in detail.



   As stated previously, the negative pulse appearing at the anode of the tube FI and which is used to modify the steady state of the rocking circuit C is transmitted to it by the connection 60 connected with a starts at the common point 55a of the resistors 55 of the anode circuit of the tube F1 and on the other hand to the control gates of the tubes C1 and C2, via the capacitors 48 and 61 of 40 pF each.



   A tap 18a of the anode resistor 18 of tube C2 of rocking circuit C is coupled to the control gate to tube D2 of rocking circuit D via connection 74 and a 40 pF capacitor 61. When the rocking circuit C goes from its OFF state to its ON state) a positive pulse is applied to the control gate of the tube D2 via this connection 74. This pulse does not modify the stable state of the rocking circuit D since, when it is applied, the tube D2 is already conauctuur as can be seen from the table below.

   However, each time the toggle circuit C goes from its ON state to its OFF state, a negative pulse is applied to the control gate of the tube D2, through this connection 74, and switches the low circuit. culât D, from its OUT state dune its EN state, as

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 we can also see it from -Labelle below.



   The meter comprises an output terminal 105 connected directly to the anode of tube D2 by connection 77.



   As will be seen later, this terminal provides one negative output pulse for each set of ten negative pulses applied to input terminal 40 of the counter.



   The positive output pulse which appears at this terminal 105 when flip-flop D goes from its OFF state to the ON state is not used.



   The operation of each of the separate toggle circuits has been described, with reference to the operation of the toggle circuit A, and the effect of the first two negative pulses applied to the input terminal 40 of the counter has been explained. We will now write all the means used to transform a binary counter into a decade counter as well as the operation of this complete decade counter, with reference to FIG. 1 and in the table below which shows the states of the tilting circuits A, B, C and D and of the tubes of these circuits E, F and G during a complete cycle of operation of this counter.

   In this table, an "X" designates the EN state of the respective rocking circuits or the conductive state of the tubes of the circuits E, F and G, but a hole designates the OFF state of these same rocking circuits or the state non-conductive of the tubes of circuits E, F and G.
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   <SEP> to <SEP> input <SEP> Tilting <SEP> circuits <SEP> Tubes
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 tamer A B c D Gl El Fi
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As shown in the table and as explained above, the first pulse applied to the input of the counter switches the rocking circuit A to the state EN and the second pulse switches this rocking circuit A to the state OFF and the rocking circuit B in the ON state.



   The third input pulse switches the rocker circuit A to the EN state and has no other effect on the counter, except that it makes the tube E1 non-conductive.



   The fourth pulse switches the flip-flop circuit A to the OFF state and the positive pulse collected 3 the anode of the tube Al makes the tube E1 conductive and thus transmits, from its anode and through the condensate. sator 44, a negative pulse to the anode circuit of the tubes to the tilting circuit B. This tilting circuit is switched to the OFF state by this negative pulse and a positive pulse produced at the anode of its tube B1 is conauite at the control grid of the tube F1, to renure this conaucteur tube.



  The decrease in potential of the anode of this tube F1 provides a negative pulse which is transmitted by the connection 60 to the control gates of the tubes of the rocking circuit C which is thus switched, from its OFF state, to its ON state. This switching of the rocking circuit C is not effective for switching the rocking circuit D, because it produces

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 a positive pulse which is applied to the control grid of tube D2 and this tube is already conductive.



   The fifth pulse switches the flip-flop circuit A to the state EN thus rendering the tube E1 non-conductive, which has no effect on the following circuits.



   The sixth pulse switches the flip-flop A to the OFF state and makes the tube E1 conductive, so that the conductance of the anode circuit of this tube provides a negative pulse which has the effect of switching the flip-flop B to the EN state. In turn, this tilting circuit B renders the tube FI non-conductive.



   The seventh negative pulse switches the tilting circuit A to the EN state and makes the tube E1 non-conductive.



   It can therefore be seen that the rocking circuits A, B, C and D are actuated in a normal binary fashion by the first seven pulses applied to the input terminal 40 of the counter, and that the means intended to transform this counter into a counter of decades have not yet started their operating cycle.



   The eighth pulse switches the flip-flop circuit A to the OFF state and makes the tube E1 conductive, as seen in the figure, and this tube in turn switches the flip-flop circuit B to the OFF state. The rocking circuit B makes the tube F1 conductive and this tube switches the rocking circuit C to the OFF state. The rocking circuit C being switched to the OFF state, a negative pulse is applied to the control gate uu tube D2 and switches the rocking circuit D to the EN state.



  When the rocking circuit D is switched to the state EN, the potential u'anoae or tube D2 increases and this increase is transmitted to the control grid of the tube Gl of the circuit

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 blocking G via connection 77, resistor 99 and resistor 54a. This tube Gl is thus made conductive. The increase ae potential of the anode of the tube D2 is sufficient to make the tube Gl conductive because the common point of the resistors 99 and 101 is brought to a high potential, because these resistors are connected in series between the line 22 at -100 V and the anode of tube D2 which is connected to line 33 at + 150 V through the anode load resistor 18 of this tube.

   When the tube
Gl is conductive, its anode potential is lowered and, since the anodes of the blocking tube Gl and the tube L1 are connected in parallel, and this tube E1 had been made conductive by the eighth pulse, the drop of potential thus produced at the anode of the tube G1 renders the tube E1 practically non-conductive. Therefore, a positive voltage applied to its control gate can no longer have the effect of producing a decrease in potential in its circuit and the pulses applied to the input to the counter are consequently ineffective in switching. the tilting circuit B, from the OFF state in which it is found, as long as this tube E1 is kept non-conductive, as will be seen later.



   The ninth pulse switches the flip-flop circuit A to the EN state and this circuit applies a negative voltage to the gate and controls the tube E1. This voltage is ineffective, since the anode potential of this tube is maintained at a low value as long as the tube G1 is conductive.



   The tenth pulse switches the flip-flop circuit A to the OFF state, and this circuit applies a positive voltage to the control gate of the tube E1. However, this positive voltage cannot produce a lowering of the potential.

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   of anae of tube E1 since the potential of this anode is
 EMI19.1
 still kept low and therefore no negative pulse is transmitted to the rocker circuit B via the capacitor 44. The rocker circuits B and C therefore remain in the OFF state, as in the case of
 EMI19.2
 table above.

   However, cetuc. positive voltage applied to the control grid at tube E1 ′ although unable to reduce the potential of the anodes connected in parallel with tubes E1 and G1, makes the screen grid circuit at tube E1 highly conductive. When this screen grid circuit of-
 EMI19.3
 thus becomes conductive, a voltage drop occurs across the terminals of the screen grid resistor 49 and a negative pulse is transmitted to the control grid of the tube D1 through the intermediary of the connection 47 and to the conaensator 48. The tilting circuit D is thus switched, from its state
 EMI19.4
 In its state 110, LiS, and a negative voltage is transmitted from the anoa of the tube u2 to the output terminal 105 to indicate that uix pulses have been counted by the counter.



  Simultaneously, a negative voltage is transmitted, from the anaea to the tube II2 and through connection 77 and resistors 99 and 54a,. the grid has been ordered at
 EMI19.5
 G1 blocking tube and this tube is thus made non-conductive.



  It should be noted that when the a'anoae circuit of the
 EMI19.6
 tube ul is namely a conductor, 1 .... drop in the potential produced at its terminals at its resistance to the screen grid 49 and transmitted to the grid to the control of the tube D1 via the connection 47 and to the capacitor 48 , is insufficient
 EMI19.7
 .) 0l.1 switch the tilting circuit J, from ae one ae beo tu;,:, stable ú ".n: ..; the other. When the tube Gl uevxent non-co: iuucteur, as one has just been written, under the effect uc! .. voltage n; .. tme transmitted by connection z and by

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 resistors 99 and 54a, its anode potential increases thus allowing the anode potential of tube E1 to increase so that this tube is no longer blocked.

   A complete cycle of counter operation is thus accomplished and the counter circuit is again in the selected initial state of zero.



   When the rocking circuit) had been switched from its ON state to its OFF state by the sixth pulse, a positive pulse had been transmitted to the control gate at the tube G1, from the anoae of the tube. D1 and through capacitor 100 and resistor 54a. This positive pulse delays the passage of the tube Gl from its conducting state to its non-conducting state, under the effect of the negative voltage applied to its control gate from the anode of the tube D2. It therefore also delays the instant at which the E1 tube becomes conductive.

   The purpose of this delay is to ensure that the switching of the rocking circuit A by the tenth pulse applied to the input to the counter does not have the effect of transmitting a negative pulse to the rocking circuit B, via the tube E1, and ae switch this switching circuit to the EN state.



   When the tube E1 is released and becomes conductive again, the rocking circuit B is not switched because the potential of the anode of the tube El was already low before this tube becomes conductive, due to the fact that the tube Gl was then conductive. . A practice, the negative impulse transmitted by the condenser 44 when the tube E1 becomes again conductive in these concilions, does not exceed 10 V of amplitude, which is much too little to switch the switching circuit B.



   The means used to block and advance arti-

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 Formally, the operation of the counter, as well as the coupling circuits of the first and of the second tilting circuit, make it possible to obtain that the counter can operate at a speed comparable to those of the tilting circuits which compose it, taken in isolation. Such a counter is capable of operating satisfactorily at pulse repetition rates of up to 550 kilocycles per second, which is much faster than any other known counter.



   However, in this embodiment, the operating speed is limited by the time constant of the circuit for coupling the anone of the tube D1 to the control grid of the tube G1. Indeed, because of the invariable delay, the unblocking of the tube El could have the effect of not switching the tilting circuit of a higher order according to B, from one of its stable states in the other, and if the constant of time is too strong, the toggle circuit B remains blocked for too long and thus prevents the operation of the next toggle circuit C, under the effect of subsequent pulses to be counted.



   The counter represented in fig. 2 and 2a do not have this drawback. It consisted of four rocking circuits A, B, C and and three separator circuits V1, V2 and V3, connected respectively between the rocking circuits A and B, B and C, and C and D. It also included switching circuits S1 and S2, a tilting blocking circuit T and a blocking circuit BL. In the diagram of fig. 2 and 2a, each of these circuits is still by dotted lines. All the electron tubes used are type 6le tetrodes, but it is obvious that any other tube showing ca- recitratic can be used.

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   As indicated, of the points shown to the right of the respective tubes which are in their conductive state, the rocking circuits A, B, C and D are all in the OFF state, at the initial state of zero of the counter, while the tubes of circuits V1, V3 and BL are conductors, the tubes of circuits V2, SI and S2 being non-conductive and the tilting circuit T being in the EN state, since its left tube T1 is conductive.



   The arrangement and the operation of the rocking circuit A will be described with reference to the values of the applied voltages, of the resistances and of the capacitances of this circuit. The operation of the rocker circuits B, C, D and T is similar to that of the rocker circuit A, except where otherwise indicated.



   The cathodes 10 of the tubes A1 and A2 to the rocking circuit A are connected to a line 11 of zero potential and their anoaes 12 are connected to a line 13 at + 190 V: the anode of the tube Al via ae resistors 14, 15 and 16 connected in serit. and the anoaa of tube A2 through resistors 17, 18 and 16 also connected in series. Resistors 14 and 17 are 47 ohms each, resistors 15 and 18 are 1000 ohms each, and common resistance 16 is 535 ohms.

   A connection 19 connected from the common point of the resistors 17 and 18 couples the anode of the tube A2 to the control grid at the tube A1 by means of a voltage divider formed by the resistors 20 and 21 of 33. 000 ohms each. The resistor 20 of this voltage divider is linked to connection 19 while its resistor 21 is linked to a line ae polarization 22 at -100 V. A capacitor 23 of 213 pF shunts resistor 20 and the common point aes

 <Desc / Clms Page number 23>

 resistors 20 and 21 is connected to the control grid of the tube A1 through a resistor 24 ae 330 ohms for suppressing parasitic oscillations.



   Similarly, a connection 25 connects the common point of resistors 14 and 15 to a resistor 26 of a voltage monitor comprising this resistor and a resistor 27 of 33,000 ohms each. A 213 pF capacitor 28 shunts resistor 26 and the common point of resistors 26 and 27 is connected to the control grid of tube A2 through resistor 29 of 330 ohms. The other resistor 27 of this voltage divider is connected to a line 30 for removing polarization at -100 V. This line is provided with a switch for removing polarization CBS, provided for re-installation. rescues the rocking circuit to the initial state by a simple momentary interruption of the circuit controlled by this switch.

   When the CBS switch is open, the poten-
 EMI23.1
 tiel at the grid commanded by Lube A2 increases until future 1;: rvmm greater than zero, so bie .. that this tube n2 becomes conductive. The I \ ;; rm1.ur subsequent to the i; .1.rru1.eur CBS puts the circuit back into working order, all the switching circuits .i1 ...... ln; c ....! 1S their respective initial states and the tube A2 remains conductive until the stable state of the rocking circuit A is modified by applying to this circuit a negative pulse of suitable characteristics.



   It should be noted that all resistance
 EMI23.2
 1-ncicc Q 1: "" "10U used in this cO -: '1.t.:ur are of the wound type and have a% - power consumption at 10 watts. These resistances are much lower ohmic values that the corresponding r -is L-, ic .- ,, 3 used in known counters. We have l..l! J..J.r'1u .: that the inauctance Qe these resistors bobi -

 <Desc / Clms Page number 24>

 The speed of operation of the counter can be increased.



   The screen grids of the tubes A1 and A2 are joined together by means of resistors 31 and 32 for suppressing parasitic oscillations. These resistors are 100 ohms each and their common point is connected to a line
33 to + 400 V via 1 via a 34 ae 535 ohm resistor, and at zero potential line 11 via a capacitor
35 of 0.05 microfarads.



   A filter capacitor 36 is connected between the + 400 V line and ground and a filter capacitor
37 is connected between line 22 at -100 V and ground as well.



   Each toggle circuit has two stable states, and is connected so as to provide an output signal to drive the next higher order toggle circuit under the effect of every second input pulse it receives. Thus, during the ordinary binary operation of such a counter, each toggle circuit operates at a speed twice that of the immediately higher toggle circuit a'orare, the first toggle circuit operating at the rate of application of the input pulses applied. at the meter.



  Therefore, in order to obtain a high operating speed of the entire counter, it is most necessary to increase the intrinsic maximum operating speed of the first and second rocking circuits. For this purpose, the rocking circuits A and B are switched, from one of their stable states to the other, by negative pulses applied to their respective anode circuits. This switching mode is called anode control.



   An input connection 38 is connected to the point

 <Desc / Clms Page number 25>

 common 40 of the resistors 15, 18 and 16 to the anode circuit of the tilting circuit A via a capacitor 39, to control this tilting circuit by anode control.



  This input terminal is intended to be connected to a source of negative pulses to be counted, these pulses having characteristics suitable for modifying the stable state of the rocking circuit A.



   Positive pulses at an amplitude equal to that of the negative pulses to be counted cannot modify the steady state of any tilting circuit, these circuits being dimensioned so as to be insensitive to positive pulses.



   When a negative pulse is applied to terminal 38, it has the effect of reducing the potential of the anodes and of the control gates of the tubes A1 and A2. The reduction in the potential of the control grid of the tube A1 has no direct effect since this grid is already pumped below the cut-off potential of this tube. The decrease in potential of the control grid of tube A2 renders this tube non-conductive and the resulting increase in its anode potential is transmitted to the control grid of tube A1, via the tube. resistor 20, shunted by capacitor 23 and resistor 24.

   The grid concerning this tube is thus reduced relatively positive and the tube A1 becomes conductive, which leads to a reduction in its anode potential. The decrease in the anode potential of tube Al is transmitted to the switching grid: to tube A2 via resistor 26, shunted by capacitor 27 and resistor 29. In accordance with the cumulative ef-et bien known, the tube A2 is thus maintained

 <Desc / Clms Page number 26>

 in its non-conductive state until the next native pulse is applied to terminal 38.

   Thus, we see that the first negative pulse applied to the terminal
38 switches the rocking circuit A, from its OFF state shown in the diagram, to its EN state.



   When the toggle circuit A changes from its OFF state to its EN state, a negative impulse is transmitted from the anae of the conductive tube A1 to the control grid of a separator tube VIT of the separator circuit
VI, via connection 25, resistor 41, shunted by capacitor 42 e of suppression resistor 43. This pulse polarizes this control grid of the VIT tube down to below the cut-off potential. pure and reborn this non-conductive tube.



   The anode of the tube V1T is connected to the common point of resistance 15, 18 and 53 of the avowed circuit of the tilting circuit B, by the intermediary of a capacitor 44 of
100 pF. This anoae is also connected to line 13 at +190 V through a 1200 ohm resistor 45, shunted by a 1000 ohm resistor 46. A tap 46a of resistor 46 is connected to the control grid of tube D1 to the rocker circuit D, via a connection 47 and a capacitor 48 of 40 pF. The screen grid to the VIT tube is connected to line 53 at + 400 V, through a 22,000 ohm resistor 49, and to zero potential line 11 through a capacitor. 50 of 30,000 pF.



   Tilting circuit B is similar in its large lines to tilting circuit A. It includes condensate 51 and 52 of 250 pF each, bypassing resistors 2o and 26, respectively. A resistor 53 of 600

 <Desc / Clms Page number 27>

 ohms is connected between the common point of the anode resistors 15 and 18 and the. line 13 to + 190 V.



   Switching the toggle circuit B from its ON state to its OFF state only momentarily conducts the V2T tube, because of the presence of a coupling capacitor 42.



   The variations in potential occurring in the anode circuit of the tube B1 are transmitted to the control grid of a tube V2T to the separator circuit V2 through a connection 25, the capacitor 42 and a resistance 54 to 100 ohms, suppressing parasitic oscillations. The anoa to the V2T tube is connected to line 13 at + 190 V by a resistor 55 ce 570 ohms, its screen grid is connected to line 33 at + 400 V by a resistor 56 of 24,000 ohms and is decoupled by a capacitor 57 of 30,000 pF connected on the other hand to the line 11 of zero potential.



  Two gate leakage resistors 58 and 59, of 150,000 and 300,000 ohms respectively, are pinned between the common point of the capacitor 42 and the resistor 54 and the lines 11 and 22 respectively. These resistors serve to keep the DC bias potential of the control grid at the V2T tube at an average value negative enough to prevent the weak pulse, produced at 11-knot at the B1 tube below the ef- and ae the tenth pulse applied to the counter, to switch the rocking circuit C.



   This V2T separator tube is capacitively coupled to the tilting circuit which precedes it, but the other separator tubes are conauctively coupled to the respective tilting circuits which precede them.



   The variations of the anode potential at tubd @

 <Desc / Clms Page number 28>

 
V2T are transmitted to the control grid at the tube C1 of the rocking circuit C, via a connection 60, a rectifier 62, a capacitor 48 of 40 pF and a suppression resistor 24. They are likewise transmitted to the control grid of tube C2 of rocking circuit C, via the same connection 60, a rectifier 63, a capacitor ol of 40 pF and a suppression resistor 29.



   Rectifiers 62 and 65 are type 1N27 germanium crystal rectifiers. During meter operation, the control grids of the tubes of each tilting circuit are normally in phase opposition to each other. However, as the speed of the count increases, the capacitive reactance between these gates decreases until these two gates keep dragging each other.

   thus preventing the normal operation of the tilting circuit and limiting the operating speed of the meter. The rectifiers 62 and 63 eliminate this tendency for these wings to drive each other and effectively decouple them by allowing current to flow from each gate and preventing current. ae establish itself from one of these grids to the other. For this purpose, other types of rectifiers could be used, such as for example these electronic tubes of the diode type.



   The switch circuit C to switch circuit comprises an 800 ohm resistor 64 connected / in series with resistor 14 in the anode circuit at tube C1 and corresponding to the. resistor 15 of the rocking circuit A. It also comprises a resistor b5, common to the anode circuits of the tubes C1 and C2 and corresponding to the resistor 16 of the circuit

 <Desc / Clms Page number 29>

 tilting A. The screen grids of the tubes of tilting circuit C are interconnected, like those of the tubes of tilting circuits A and B, by means of suppression resistors 31 and 32.

   In the toggle circuits B and C, the common point of these resistors is connected to line 13 at + 190 V by a resistor 66 ae 1000 ohms and to line 11 of zero potential by a capacitor 67 of 30,000 pF. The common point 68 of resistors 64, 18 and 65 of the uano-wave circuit to the rocking circuit C is connected to the zero potential line 11 by a capacitor 69 of 16 microfarads. This capacitor serves to maintain this point 68 at a substantially constant potential.



   The variations in the anode potential of the tube C1 of the rocking circuit C are transmitted to the control gate of a tube V3T of the separator circuit V3, via a connection 25, a capacitor 42, a 'a resistance 71 of 130,000 ohms and a suppression resistance 54 (fig.



  2a). The anoue of the V3T tube is connected to line 13 at + 190 V by a resistor 72 of 460 ohms and its screen grid is connected to line 33 by a resistor 73 of 39,000 ohms. A 25 pF feedback capacitor 74, connected between the anoue to the V3T tube and its resistor 54, improves the shape of the output signal supplied by this tube. This output signal is transmitted to the control gate to the tube D2 of the rocking circuit D, through a connection 75, a capacitor 61 and a suppression resistor 29. It has the effect of switching the tilting circuit D, from its OFF state uans its EN state, when the tube V3T is renau comducteur.



   The anode circuits of tubes D1 and D2 are

 <Desc / Clms Page number 30>

 connected to line 13 a + 190 V by a common resistor 76.



  The variations in the anaae potential at tube D2 are passed through the control gate to a switch tube S1T of the switch circuit S1, through a connection 77, of a resistor 78 of 100,000 ohms. , shunted by a 100 pF capacitor 79 and a 1200 ohm suppression resistor 80. This controlled grid is connected to a line 82 at -270 V by a leakage resistor ae grid 81 ae 360. 000 ohms. The screen grid of the tube S1T is connected to line 33 at + 400 V by a resistor 83 of 2500 ohms and to line 11 with zero potential by a condenser 84 with 30,000 pF.



   An 85 ae 1100 ohm resistor, connected between the 13 a + 190 V line and the anoaes of the switch tubes S1T and S2T, serves as the common anoa load resistor.
 EMI30.1
 for these two tubes. The grid comr., Anue to the tube 32T is connected to the zero potential line 11 through a suppression resistor 80 and a resistor 86 of 180,000 ohms. A resistor 87 ae 360. 000 ohms is connected between the common point of resistors 80 and 86 and line 22 at-100 V. This same control grid is still
 EMI30.2
 connected to 11-end to the separator tube VIT by 1 intcrr.éuiire of its suppression resistor 80, a capacitor 88 and a connection 89 (fig. 2 and 2a). It thus receives a positive pulse each time the VIT tube becomes non-conductive.
 EMI30.3
 



  The V ".ri ..." t1ons of potential at a tap 90 to the resistance 85 to the circuit anoaes to the switched tubes S1T and S2T. Are transferred to the grid to control a tube Tl to the circuit b3Culnt ae blocking 'l', by the

 <Desc / Clms Page number 31>

 a connection 91, a capacitor 48 and a suppression resistor 24. The tilting circuit T is thus switched and goes into its OFF state at the instant "1" of each operating cycle of the counter, to release the circuit. BL blocking. The part of resistor 85 between point 90 and line 13 is 665 ohms, the part between point 90 and the anodes of the tubes S1T and 32T being 435 ohms.



   The variations in potential of the anode circuit of the tube D1 to the tilting circuit 1) are transmitted to the control grid of the tube T2 to the locking tilting circuit T, via a connection 92, of a rectifier 93, has a capacitor 61 and has a suppression resistor 29. The rectifier 93 is a germanium crystal rectifier of type 1N34.



   Resistors 94 and 95, respectively of 1000 and 800 ohms, are arranged in the circuit aes anones aes tubes T1 and T2 and are connected together, their common point being joined to line 13 at + 190 V by a resistor 96 of 1200 ohms and at zero potential line 11 by a 5 microfarad capacitor 97.



   The variations in potential produced in the anode circuit of the tube T2 are transmitted to the control grid or from a blocking tube BLT to the blocking circuit BL, through the intermediary of a connection 98, or a resistor 99 of 100,000 ohms, shunted by a 100 pF capacitor 100 and a suppression resistor 54a.



   The control gate of the BLT tube is connected to line 82 at -270V, through the aite resistor 54a and a resistor 101 of 300,000 ohms, and its

 <Desc / Clms Page number 32>

 screen grid is connected to line 33 at + 400 V by a resistor 102 of 2500 ohms and to line 11 ae zero potential by a capacitor 103 of 50,000 pF. The anoe to the tube
BLT is connected to the common point aes resistors 17 and 18 to the anode circuit at the tube B2 to the tilting circuit B by a connection 104 fig. 2a and 2).



   The resistances to suppressing parasitic oscillations connected to the control gates of the tubes B1, B2,
Cl, C2, Dl, D2, Tl, T2 and BLT correspond to the resistances
24 and 29 of the grid circuits controlled by tubes A1 and A respectively, except that they are 100 ohms each instead of 330. Likewise, the suppression resistors connected to the screen grids of tubes B1, B2, C1 , C2, Dl, D2,
T1, T2 and BLT correspond to the resistances 31 and 32 of the screen grids of the tubes A1 and A2 respectively.



   The switching of the toggle circuit A, from the OFF state to the ON state, under the effect of the first negative pulse applied to the terminal 38, has been explained above. This toggle circuit A is similarly switched from the ON state to the OFF state when the second native pulse is applied to this terminal 38. The negative pulses followed applied to this terminal on. the effect is a repetition of the switching caused by the first and by the second pulse.



   The complete cycle of operation of the meter will be described below with reference to the diagram of fig. 2 and 2a and in the table of FIG. 3 which shows the state of each toggle circuit, to each separator tube, to each switch tube and to the BLT blocking tube for each counter position. In the table of fig. 3 an "X" in

 <Desc / Clms Page number 33>

 the column of a tilting circuit indicates that this circuit is in the EN state and an "X" in the column of a tube indicates that this tube is conductive, while a "0" indicates that the circuit tilting is in the OFF state or the tube of the column considered has non-conetor.

   In these V2T and S2T tubes, the negative pulses represented by the indication "NP" signify that these V2T and 32T tubes are momentarily conducting at the position of the counter considered, their anode potential thus being momentarily relatively negative.



     The state of each element on the counter after the application of the first / negative pulse is shown on line "1" of the table in fig. 3. When the toggle circuit A is switched OFF by the second pulse applied to the input of the counter, the increase in anode potential of the non-conductive tube Al is transmitted to the grid. control of tube VI, through line 25, resistor 41, shunted by capacitor 42 and resistor, running the conductive tube V1 and reducing the potential of its anode.



   This decrease in potential is transmitted to the common point ues resistors 15, 18 and 53 of the anode circuit of the tilting circuit B, by the capacitor 44, switching this tilting circuit from its OFF state to its ON state.



    When the rocking circuit B is switched in its state EN, the decrease in potential from the anode to the tube B1 is transmitted or to the control grid of the tube V2T, through connection 25, the capacitor 42 and ae resistor 54, Retorts the V2T tube is already non-conductive, this aiminution uc potaneld has no effect on it.

 <Desc / Clms Page number 34>

 



   The decrease in the anoa potential of the VIT tube, caused by the fact that this tube is renal conductor, is transmitted to the control grid of the tube D1, from the tap 46a of the resistor 46 and through the intermediary of the connection 47, of the capacitor 48 and ae the suppression resistor 24 (fig. 2 and 2a). This negative pulse has no effect because the D1 tube is already non-conductive. The rocking circuit D therefore remains in the OFF state, as indicated on line "2" of the label of FIG. 3.



   This decrease in the anoa potential at the VIT tube is also transmitted to the control gate at the switch tube S2T, via connection 89 (fig.



  2 and 2a), capacitor 88 and resistor 80. This switch tube is thus momentarily conuucteur.



   The third negative pulse applied to terminal 38 switches the toggle circuit A into its EN state. The decrease in the potential of the anoae at the Al tube is transmitted to the controlled grid of the VIT tube and again. this non-conductive tube. A positive voltage pulse is then transmitted to the grid ae common to the tube Dl to the rocking circuit D, from the socket 46a and through the connection 47 (fig. 2 and 2a), of the capacitor 48 t of the resistance 24.



  This positive pulse has no effect and the D rocker circuit remains in the OFF state. Simultaneously, a positive pulse is also transmitted to the control grid of the S2T tube, from the anode circuit to the VIT tube and through connection 89 (fig. 2 and 2a), to the capacitor. 88 and resistor 80. This tube S2T is thus made momentarily conductive, as indicated on line "3" in the table of FIG. 3.

 <Desc / Clms Page number 35>

 



   The fourth input pulse switches the flip-flop circuit A to its OFF state and this flip-flop A circuit makes the VIT tube conductive. The negative pulse which is then transmitted, from the anode circuit of this VIT tube and via connection 89, to the control grid of the tube S2T, returns this momentarily non-conducting tube. The negative pulse transmitted from the anode of the VIT tube to the common point of the resistors 15,18 and 53 of the anode circuit of the rocking circuit B, through the capacitor 44, switches this rocking circuit into its OFF state. . The increase in the potential of the anode of tube B1 is transmitted to the control grid of tube V2T, through connection 25 and capacitor 42.

   This V2T tube is thus made momentarily conductive and the decrease in the potential of its anode is transmitted to the control gates of the two tubes at the rocking circuit C, via connection 60, and switches this rocking circuit to the EN state.



   The fifth input pulse switches the rocker circuit A to its EN state and this makes the VIT tube non-conductive, so that a positive pulse is transmitted to the control grid at tube S2T, through the VIT tube. intermediate connection 89 and the capacitor 88, and. that this tube is momentarily conducive.



   The sixth non-input pulse switches the rocker circuit A into its OFF state. This becomes conductive the VIT tube which switches the tilting circuit B in its EN state and also rena the non-conductive tube S2T.



   The seventh input pulse switches the toggle circuit * to its ON state. This reborns the non-conductive VIT tube, thus making the 32T tube momentarily conductive.

 <Desc / Clms Page number 36>

 



   The eighth input pulse switches the tilting circuit A to its OFF state and this turns the VIT tube on. When the VIT tube becomes conductive, it switches the tilting circuit B to its OFF state. The increase in the potential of the anode at the tube B1 thus produced is transmitted to the grid ae controlled by the tube V2T by connection 25 and makes this tube momentarily conforming. In its turn, this then switches the rocking circuit C to its OFF state, which makes the tube V3T conductive. The decrease in the potential of the anode of the tube V3T is transmitted to the control grid to the tube D2 of the rocking circuit D by the connection 75 and by the conuensator 61 and switches this rocking circuit D in its state EN .

   When the rocking circuit D is switched to its state EN, the increase in the potential of the anoae of its tube D2 is transmitted to the control grid of the tube S1T by the connection 77 and rena this conductive tube.



  The decrease in the potential of the anode of the tube D1 is simultaneously transmitted to the control grid at the tube T2, via the connection 92, the reuressor 93 and the capacitor 61. This tube T2 is thus returned non- conductor and the tilting circuit T is therefore switched to its EN state. When the toggle circuit 1 is switched to its EN state, the increase in the potential ae the anoa at the T2 tube is transmitted to the control gate at the blocking tube BLT, via connection 98, of the risistan- ce 99, shunted by capacitor 100 and resistor 54a.

   This blocking tube is thus renau conductive and, since its anode is connected, by line 104, to the circuit ae the control grid of the tube B1 and to the circuit from the anode to the tube B2, the rocking circuit B is thus blocked and not

 <Desc / Clms Page number 37>

 may be switched to its AS state as long as this BLT remains conductive.



   The ninth input pulse switches the circuit A toggled in its EN state and this makes the tube V1T non-conducting. In accordance with the previously described mode of operation of the counter, the tube S2T should be made conductive, because the tube V1T becomes non-conforming under the effect of this ninth input pulse. However, the arrangement in the circuit described has the effect of preventing the state of the tube S2T from being muffled by the fact that the VIT tube becomes non-conforming. Since the anodes of both S1T and S2T tubes are connected to a common anode load resistor 85, these two anodes are maintained at a relatively low potential when any of these tubes is conductive.

   Due to this parallel connection of the anodes of the S1T and S2T tubes, the positive pulse applied to the control grid of the S2T tube, through connection 89, under the effect of this ninth input pulse, has no effect for further lower the anode potential of the S1T6 and S2T tubes. Thus, no appreciable negative impulse is transmitted to the control grid of the tube T1 and the rocking circuit T remains in its EN state, as can be seen on line 9 in the table of FIG. 3, and the blocking circuit BL continues to block the rocking circuit B.



   The tenth input pulse switches the rocker circuit A to its OFF state and this turns the tube VIT on, thus providing a negative pulse to the rocker circuit B. This negative pulse is unable to change the steady state to the circuit. tilting B, because the blocking tube BLT is conductive and it maintains, by

 <Desc / Clms Page number 38>

   the intermediary. of line 104, the grid ae controlled by tube B1 and the anode of tube B2 at a potential low enough to prevent switching of tilting circuit B.

   However, the tube B1t having become conaucer at this instant, the decrease in its anode potential is transmitted to the control grill of the tube D1, from the tap 46a of the resistor 46 and via of connection 47. The rocking circuit D is thus switched to the OFF state and the decrease in the potential of the anode of its tube D2 is transmitted to the control grid of tube S1T, by connection 77, so that this tube is made non-conductive.

   This same decrease in the potential of the D2 tube custard apple, occurring under the effect of each tenth pulse before Sire counted, indicates that the counter has gone through a complete operating cycle of the arcade and can be used to control the operation of suitable devices connected to this meter. The increase in the potential of the anoa at tube D1, which is capacitively coupled to the control gate at tube T2, tends to switch the tilting circuit T, thus making operation unstable.

   The reuressor 93, with a germanium crystal uu type 1N34, is designed to prevent a modification to the potential of the control grid at the T2 tube under the effect of the increase in the potential of the anode of the Dl tube and to make thus the operation with the tilting blocking circuit T perfectly stable.



   The operating cycle for the blocking circuit of this meter does not end with the cycle for operating the meter, I would go with the. fruction in the next cycle comprising the position 'la of the counter. The first implasion of this next cycle switches the tilting circuit

 <Desc / Clms Page number 39>

 
A in its EN state and this one rand the non-conductive VIT tube
The increase in the potential of the anoue to the VIT tube is transmitted to the control grid of the S2T tube through connection 89 and makes this tube conductive. When the tube S2T becomes conductive, the decrease in potential at the tap 90 of the resistor 85 is transmitted to the switch grid at the tube T1 of the rocking circuit T through the connection 91.

   This tube is thus renal non-conductor and the tilting circuit T is switched to its OFF state. When the toggle circuit T thus goes into its OFF state, the decrease in the potential of the anode of the conductor tube T2 is transmitted to the control grid of the tube BLT by the connection 98. This tube is thus rendered non-conductive and the toggle circuit B is thus released, until the eighth input pulse of this new cycle of operation to the counter is applied to terminal 38.



   It can be seen that the non-blocking circuit becomes effective under the effect of the eighth pulse to be counted and that it becomes ineffective again under the effect of the first pulse in the cycle following operation of the counter. The operation of this blocking circuit is therefore effective curant the passage to the counter by its zero position and ensures a uniform operation of this counter, under the effect of each ten pulses uevant draws counted, whatever the rate at counting.



   It should be emphasized that the described blocking circuit has become ineffective under the effect of a pulse which common the rocking circuit A in its EN state. When the rocking circuit * is switched to its EN state, it makes the bue-VIT non-conductive and this switching does not auche tancahce to cause the switching of circuits

 <Desc / Clms Page number 40>

 following rockers, since there is then no negative pulse transmitted from the VIT tube.

   It follows that by rendering the non-blocking circuit ineffective at such an instant, any probability of voltages applied to the blocked circuits not effecting a switching as these circuits and a toggle circuits follow is eliminated.



   By arranging the control in the blocking circuit so that its operating cycle includes the output signal or the initial zero state of the counter, using an anode control for the first and for the counter. second toggled circuit, and rectifying means for preventing high frequency short circuits between the interconnected control gates of the tubes of toggled circuits and by separating each toggling circuit from the others so as to eliminate any capacitive effect between these circuits, one obtains a meter capable of operating stably and accurately at a much higher speed than known meters.

   The counter described with reference to FIGS. 2 and 2a operated satisfactorily at speeds between two cycles per second and 3.5 megacycles per second.



   In summary, the counters described are ten-decade counters held from counters of binary structure, in which case any interaction between the tilting circuits electronically coupled to one another is prevented. These counters both include electron tube separator circuits with reduced input capacitance. This separator circuit is connected to a first toggle circuit and coupled to a second toggle circuit so that the load imposed on the first toggle circuit when pulses are applied to the second circuit.

 <Desc / Clms Page number 41>

 cooked tilting from the first is considerably reduced.

   These counters include means for applying the output signal to the first rocking circuit to the fourth rocking circuit, so as to modify its stable state at a determined instant of the cycle of operation on the counter, without connecting an additional load circuit to this first. tilting circuit.



   The counters described include a control grid tube disposed between the first and the second tilting circuit and serving to fulfill three different functions: preventing an electrical interaction between these two tilting circuits, transmitting a pulse to the second tilting circuit while maintaining the load imposed on the first tilting circuit to a very low value, to transmit a pulse to a fourth tilting circuit to make it operate at a determined instant of the cycle of operation of the counter. In the first counter described, this same tube is also used to prevent the operation of a second tilting circuit under the effect of a signal from the output of the first switching circuit, at the moment when it transmits a pulse to the fourth tilting circuit.

   This counter comprises a blocking circuit comprising an electron tube which is made conductive by a change in the stable state of the fourth rocking circuit, under the effect of the eighth pulse applied to the input of the counter. This blocking tube maintains.,. During the potential of the control grid tube arranged between the first and the second rocking circuit at a low value, so as to prevent the stable state of the second rocking circuit. is changed when the first rocking circuit is switched, from its

 <Desc / Clms Page number 42>

 ON state in its OUT state,

   by the tenth pulse applied to the input of the counter. The separator circuit with electronic tube arranged between the first and the second bottom circuit of this meter has the effect of reducing in aes considerable proportions the consequences of the capacitance between the tubes of the first and of the second tilting circuit and of allowing thus to increase their own speed of operation as well as the speed of operation on the meter.



  The operating speed of this counter is further increased by the fact that the first and second tilting circuits are controlled by negative pulses applied to the anoaes of their tubes, and not to their control gates.



  The pulses supplied at the output of the various tilting circuits are amplified and their shape is improved by the separator tubes, which makes it possible to further increase the upper limit of the operating speed at the meter.



   The counter described with reference to FIGS. 2 and 2a comprises aes means for preventing any interaction between the interconnected control gates of the tubes of each tilting circuit, when this counter is operated to operate at high speeds. It xcomprend blocking means arranged to transform it into a decade counter, these means being effective for a number of determined counter positions including its initial ziro or counting position. This blocking circuit is automatically made effective, in a time-controlled manner by the counter, whatever its initial state when the counter begins to operate.

   This same blocking circuit is rendered ineffective by switching a toggle circuit to that of its stable states in which it does not tend to cause any other toggle circuit to switch.

 <Desc / Clms Page number 43>

 



   The new and fundamental features of the invention have been described and demonstrated in their application to aeux embodiments of electronic meters. It should be understood, however, that various omissions, substitutions and modifications, in the form and in the details of the meters described and shown, as well as in their operation, can be made by those skilled in the art, without departing from it. the spirit of invention.



    CLAIMS
1) Electronic meter comprising several tilting circuits linked together ae so as to form a chain, each of these tilting circuits comprising a pair of electronic tubes with control grid coupled in a cross so that one of these tubes passes through a conductive stable state to a non-conductive stable state and vice versa, and that the other passes simultaneously from a non-conductive stable state to a conductive stable state and vice versa under the effect of electric pulses, characterized in that the first of said rocking circuits is that having the highest natural operating speed, the second having a higher inherent operating speed than the following rocking circuits.


    

Claims (1)

2) Meter according to claim 1, charac- terized in that an electron tube with a control grid, said separator tube, is interposed between successive tilting circuits to prevent an interaction by capacitance between at least two of these circuits and is used to order the state of <Desc / Clms Page number 44> upper orare tilting circuit in the chain which is arranged after it. 3) Meter according to claims 1 and 2, characterized in that said separator tube is renau operating by a lower a'orare tilting circuit and in that means comprising at least one electron tube are disposed between such separator tube and an upper orare tilting circuit to render this tube inoperative and prevent it from controlling the stable state of the upper tilting circuit, during a selected part in advance of the cycle of operation of the counter. 4) Meter according to claims 1 and 2, characterized in that said separator tube comprises at least those grids and serves to switch the stable state of the higher order tilting circuit disposed thereafter, under the effect of u 'a switching of the stable state uu tilting circuit lower orare and setting an interval this counting chosen in advance, a connection connecting one of the gates of this separator tube to a tilting circuit of higher order to switch its stable state during the remaining counting interval. 5) Meter according to claims 1, 2 and 4, characterized by an electron tube arranged between said separator tube with several grids and the higher order tilting circuit and controlled by the latter to give the monk a tilting circuit of ' intermediate order, arranged between this separator tube and this higher order tilting circuit, insensitive to a switching u'un any lower tilting circuit, during the counting interval chosen in advance. <Desc / Clms Page number 45> 6) Meter according to claims 1, 2 and 4, characterized in that said chalnt comprises four tilting circuits each comprising a first and a second control grid tube, the control grid a'un first separator tube with several grids being connected to the control grid uu the second tube of the first tilting circuit, a second grid of this same tube being connected to the control grid of the first tube of the fourth tilting circuit to change its stable state at a time chosen in advance during each cycle of operation at the counter and its anode circuit being counted capacitively at the anode circuit of the second tilting circuit to change its stable state cyclically determined in advance. 7) Meter according to claims 1, 2, 4 and 6, characterized by a second separator tube disposed between the second and the third tilting circuit to change the stable state of this last under the effect of a change of stable state of the second rocking circuit, by a coupling between the anode circuit of the third rocking circuit and the control grid of the second tube of the fourth rocking circuit and by a blocking electron tube whose anode is rIje to the anode of the first separator tube to prevent a current from passing through the anode circuit of this tube at the eight time chosen in advance and the control gate of which is coupled by resistance to the anode circuit of the fourth rocking circuit. 8) Meter according to claims 1, 2, 4, 6 and 7, characterized by a capacitor connected between the circuit u'unode of the fourth tilting circuit and the control grid of said blocking tube. <Desc / Clms Page number 46> 9) Meter according to claims 1, 2 and 4, characterized in that the aite chain comprises four tilting circuits each comprising a first and a seconu control grid tube, by a non-input connection connected to the circuit a'anoae to the first rocking circuit to transmit electrical impulses to it to be countered, by an output connection connected to the anoe to the second tube to a fourth rocking circuit to provide an electrical pulse under the effect of every tenth pulse applied to the input connection, and by a separator tube with several grids, the control grid of which is connected to the control grid of the second tube of the first rocking circuit and of which the anode circuit is connected to the anoae circuit of the second rocking circuit to switch the stable state of this second toggle circuit whenever the first toggle circuit passes from a determined stable state to the other, except when it thus changes stable state under the effect of said tenth pulse . 10) Meter according to claims 1, 2,4 and 9, characterized by a connection connecting the. screen grid from said separator tube to the control grid to the first tube to the fourth tilting circuit and serving to switch the stable state of this tilting circuit, when the cathode-shielding grid circuit at the separator tube is conductive under the effect of the tenth impulse. 11) Meter according to claims 1, 2,4, 9 and 10, characterized by an electron tube ae blocking cont the control grid is read back to the anode at the seconu tube to the fourth tilting circuit and aont the anone is linked to the anode with the separator tube to repair the circuit <Desc / Clms Page number 47> anode has this practically non-conductive tube when the second tube to the fourth tilting circuit becomes conductive and to make this anode circuit conductive when the second tube to the fourth tilting circuit is made positive by 1- conductivity to the cathode circuit. screen grid of this separator tube. 12) Meter according to claims 1, 2,4, 9, 10 and 11, characterized by a second separator tube arranged between the second and the third rocking circuit to provide an actuation pulse to this third rocking circuit when the second rocking circuit is switched from one of its stable states determined in the other. 13) Meter according to claim 1, charac- terized by an electron tube arranged between two successive tilting circuits and serving to apply a voltage to the highest order tilting circuit when a voltage of polarity chosen in advance is transmitted to this tube from the lower order rocking circuit, by a connection connecting this tube to another higher order rocking circuit to switch it from one of its stable states to the other and by an electron tube a so-called blocking control gate, the anode of which is read back to said highest order tilting circuit to make it cyclically insensitive to some of said electrical pulses to be counted and constituting input signals . 14) Meter according to claims 1, 2 and 15, characterized in that such a separate tube is disposed between each of said tilting circuitc and the next, of higher order, of said chain. 15) Counter according to claims 1 and 13, <Desc / Clms Page number 48> characterized by a toggle blocking circuit having two stable states and for controlling the conductance of said blocking tube, and by means for controlling the switching of said toggle circuit ae blocking, from any of its stable states in the other. 16) Counter according to claims 1, 13 and 14, characterized in that the a'anoae circuit ae each of the tubes of each of the aits tilting circuits comprises at least one separate wound anode load resistor. 17) Meter according to claims 1, 13 and 15, characterized in that said tilting blocking circuit comprises two electronic tubes with control gate and in that said switching means of this tilting blocking circuit comprise a pair of electronic tubes with control grid, called switching tubes, connected to a common a'anoae charging circuit and to the control grid of one of the tubes of said locking tilting circuit and provided for switch this to one of its stable states from the other. 18) Meter according to claims 1, 13, 15 and 17, characterized in that said means ae switching of the locking tilting circuit further comprises a connection connecting the other toggle circuit has higher order to the Grill \ .: de control of the other tube of this tilting blocking circuit and serving to switch the latter into its other stable state. 19) Meter according to claims 1,13, 15 and 17, characterized in that said switching means uu tilting blocking circuit additionally comprise a connection connecting the other tilting circuit of higher order to the control gate of the 'one aits tubes <Desc / Clms Page number 49> switch and a connection connecting said tube arranged between two successive rocking circuits to the gate not controlling the other switching tube. 20) Meter according to claims 1 and 13, characterized in that said chain comprises four tilting circuits each comprising a first and a seconu control grid tube, said tube being disposed between the first and second tilting circuit and being connected to the control grid to the first tube to the fourth tilting circuit. 21) Meter according to claims 1, 13 and 20, characterized in that the anode of said blocking tube is connected to the anode circuit of the second tube of the second rocking circuit to reset this rocking circuit sensitive to each first pulse and insensitive at each eighth pulse a'uneseries no electrical pulses to be counted and thus operate this counter as a decade counter. 22) Counter according to claims 1, 13,14, 20 and 21. 23) Meter according to claims 1, 13,14, 20 and 21, Characterized in that the first and the second tilting circuit are switched by signals applied to the anodes of their tubes and in that the third and the fourth rd are switched by signals applied to the control gates of their tubes, the anoae to the tube disposed between the secona and the third circulated toggle jtant connected to the control grid ae each of the tubes to the third circuit toggled through rectifiers arranged to prevent current from flowing to any of these grids and the anode to the tube disposed between the third and the fourth rocking circuit being connected to the control grid <Desc / Clms Page number 50> command u secona tube of the fourth tilting circuit. 24) Meter according to claims 1, 13, 14, 20,21 and 23, characterized by means comprising at least one tube, arranged between the fourth tilting circuit and the blocking tube, serving to excite this tube ae blocking and com- driven by the fourth tilting circuit and by the tube placed between the first and the second tilting circuit. 25) Meter according to claims 1, 13, 14, 15,20, 21 and 23, characterized in that said switching means are controlled by the fourth rocking circuit and by the tube arranged between the first and the rocking circuit shook and are used to switch the toggle blocking circuit in one of its stable states and in that these switching means comprise a connection connecting the anode circuit of the first tube of the fourth toggle circuit to the toggle blocking circuit and serving to switch this toggle blocking circuit to its other stable state. 26) Meter according to claims 1,13, 14, 15,17, 18,20, 21, 23 and 25, characterized in that the first of these switching tubes is controlled after the second tube of the fourth tilting circuit and the second by the tube placed between the first and the second tilting circuit, the control grid to said other tube of the locking tilting circuit being connected to the anode circuit of the first tube of the fourth tilting circuit. 27) Meter according to claims 1,13, 15, 17,18, 20 and 21, characterized in that one aes tubes ae mutation estconducterar when the other is non-conductor and vice versa, one being comanmmdé by the secona tube / of the fourth tilting circuit and the other by the tube placed between the <Desc / Clms Page number 51> first and second tilting circuit, and in that the connection wing connects the gate to the control to the other tube of the locking tilting circuit to the first tube to the fourth tilting circuit and includes a rectifier arranged to prevent current to flow to this control gate. Claim 1 constitutes the summary within the meaning of the Royal Decree of 23 June 1877.