US2309019A - Electron discharge device circuits - Google Patents
Electron discharge device circuits Download PDFInfo
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- US2309019A US2309019A US416155A US41615541A US2309019A US 2309019 A US2309019 A US 2309019A US 416155 A US416155 A US 416155A US 41615541 A US41615541 A US 41615541A US 2309019 A US2309019 A US 2309019A
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- 230000005291 magnetic effect Effects 0.000 description 33
- 238000004804 winding Methods 0.000 description 13
- 230000004907 flux Effects 0.000 description 6
- 230000001960 triggered effect Effects 0.000 description 6
- 230000008859 change Effects 0.000 description 5
- 230000007423 decrease Effects 0.000 description 5
- 238000007667 floating Methods 0.000 description 4
- 230000001419 dependent effect Effects 0.000 description 3
- XEEYBQQBJWHFJM-UHFFFAOYSA-N Iron Chemical compound [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 description 2
- 230000001276 controlling effect Effects 0.000 description 2
- 230000003247 decreasing effect Effects 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
- 230000010355 oscillation Effects 0.000 description 2
- 230000009467 reduction Effects 0.000 description 2
- 230000035945 sensitivity Effects 0.000 description 2
- 230000009471 action Effects 0.000 description 1
- 238000005452 bending Methods 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 230000008878 coupling Effects 0.000 description 1
- 238000010168 coupling process Methods 0.000 description 1
- 238000005859 coupling reaction Methods 0.000 description 1
- 238000005188 flotation Methods 0.000 description 1
- 229910052742 iron Inorganic materials 0.000 description 1
- 239000000696 magnetic material Substances 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 239000002245 particle Substances 0.000 description 1
- 230000001105 regulatory effect Effects 0.000 description 1
- 238000000926 separation method Methods 0.000 description 1
- 239000013589 supplement Substances 0.000 description 1
Images
Classifications
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03K—PULSE TECHNIQUE
- H03K3/00—Circuits for generating electric pulses; Monostable, bistable or multistable circuits
- H03K3/02—Generators characterised by the type of circuit or by the means used for producing pulses
- H03K3/04—Generators characterised by the type of circuit or by the means used for producing pulses by the use, as active elements, of vacuum tubes only, with positive feedback
- H03K3/05—Generators characterised by the type of circuit or by the means used for producing pulses by the use, as active elements, of vacuum tubes only, with positive feedback using means other than a transformer for feedback
- H03K3/06—Generators characterised by the type of circuit or by the means used for producing pulses by the use, as active elements, of vacuum tubes only, with positive feedback using means other than a transformer for feedback using at least two tubes so coupled that the input of one is derived from the output of another, e.g. multivibrator
- H03K3/14—Generators characterised by the type of circuit or by the means used for producing pulses by the use, as active elements, of vacuum tubes only, with positive feedback using means other than a transformer for feedback using at least two tubes so coupled that the input of one is derived from the output of another, e.g. multivibrator multistable
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J21/00—Vacuum tubes
- H01J21/02—Tubes with a single discharge path
- H01J21/18—Tubes with a single discharge path having magnetic control means; having both magnetic and electrostatic control means
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03K—PULSE TECHNIQUE
- H03K17/00—Electronic switching or gating, i.e. not by contact-making and –breaking
- H03K17/51—Electronic switching or gating, i.e. not by contact-making and –breaking characterised by the components used
- H03K17/54—Electronic switching or gating, i.e. not by contact-making and –breaking characterised by the components used by the use, as active elements of vacuum tubes
Definitions
- FIG. 1 A first figure.
- An object of the invention is. to improve the means and method of regulating or controlling the on and oil properties or conditions of a trigger device comprising a vacuum tube of the secondary electron emission type.
- a feature of the invention comprises controlling the operating condition of such a trigger device by means of a magnetic field, the lines of force of which may extend either parallel to or perpendicular to the ans of the device.
- Figs. 1, 2 and 3 illustrate arrangements for associating a magnetic field with an electronic device or vacuum tube
- Fig. 4 shows a circuit arrangement in accord- I ance with the invention in which a secondary electron emission type vacumn tube has an electromagnet associated with it, as in the arrangement of Fig. l, to provide a magnetic field parallel to or along the axis of the tube;
- Fig. 5 illustrates the electrode arrangement in the tube of Fig. 4 and will be referred to inadescribing the actionof the magnetic field on the primary electrons emitted through the window or aperture in the primary anode;
- Fig. 6 is a typical operating characteristic of the tube, being a plot of magnetizing current in the magnetic field producing coil of Figs. 1 and 4 versus cathode-primary anode current, evidencing two critical primary anode current "oil” and two critical primary anode current "on” values of magnetizing current for a given set of potential conditions on the tube electrodes;
- Fig. 7 shows a family of curves illustrating how these critical off and on" magnetizing current values are aflected by variation in deflector electrode potential
- Fig. 8 is a schematic of a vacuum tube such Fig. 9 shows a family of curves illustrating how current in the coil vary with variation in deflector electrode potential, and with the direction of flow of the magnetizing current through the coil 'or electromagnet of Figs. 2 and 5;
- Fig. 10 shows a closed ring pulse counting circuit embodying the magnetically controlled secondary electron emitter vacuum trigger tube of this invention
- Figs. 11 and 12 show a modification of the circult and electrode arrangements of Figs. 4 and 5;
- Fig. 13 shows an oscillation generating circuit incorporating a trigger device in accordance with this invention.
- a vacuum tube having a trigger characteristic, i. e., it may be substantially instantaneously energized or deenergized dependent on its initial condition.
- the tube comprises a cathode;an input control grid; aprimary anode having an aperture or window therein for the passage or escape therethrough of primary electrons originating at the cathode; a secondary electron emitting electrode or auxiliary anode having an emission ratio greater than unity; a collector'electrode or grid for collecting secondary electrons released when primary electronsbombard the auxiliary electrode; and a deflector electrode for collecting cathode particles that may be released from said cathode, and for bending or deflecting from their normal paths primary electrons that pass outwardly through the aperture in the primary anode so that they may impinge on or bombard the secondary electron emitting surface of the auxiliary electrode;
- the trigger action in accordance with this invention, may be effected by magnetic or electromagnetic means, the presence or absence and the density of magnetic flux parallel or perpendicular to the axis of the tube determining whether the primary electron stream is incident on the auxiliary anode and whether the latter is at its flotation potential and the input grid at a potential substantially above cathode-primary anode current cut-H.
- Figs. 1, 2 and 3 illustrate how magnetic fluxproducing means may be associated with a vacuum tube It of the general type disclosed in my aforementioned patent.
- an electromagnet 5 shown in cross section, surrounds the tube, and when energizing current flows in the electromagnet it produces magnetic flux in a direction parallel to the axis of the tube.
- the electromagnet ii surrounds a yoke ll of magnetic material between whose ends 0 the tube is located.
- the.ei ectromagnet comprises a pair of coils t", each shown in cross section, between which the tube is positioned.
- magnetic flux may be produced that is perpendicular to the axis of the tube and at an azimuthal angle dependent on the locationof the yoke ends or of the coils 5" with respect to the tube.
- the vacuum tube l0 comprises a primary electron source or cathode ll, which may be indirectly heated; an input grid it; a primary anode i9 having an aperture or window 30 for the passage therethrough of some primary electrons; a deflector electrode 20; a secondary electron collector electrode or grid 2i; and a secondary electron emitting electrode or auxiliary anode 22, which maybe similar to the correspondingly identified elements of Figs. 1, 2 and 3 of my aforementioned patent, but with the electrode arrangement of Fig. 3A of that patent.
- a source 2% of potential is connected between the grounded cathode and the primary anode, in circuit with the primary winding of an output transformer 28.
- the collector grid is connected directly to the high potential terminal of source 2%, and the auxiliary anode is connected thereto through the resistor 21.
- the deflector electrode 20 is maintained at a positive potential which may he of the same order as that of the collector grid and primary anode, or less.
- the auxiliary anode is connected to the cathode through series-connected resistors 20, 20 and the source it of biasing potential for the grid l8, and to the latter through the tap or slide 32 engaging with resistor 20 and the secondary winding of input transformer 33.
- the resistors 27, 28, 20 are proportioned so that the auxiliary anode, in the absence. 'of primary electrons incident thereon, is at apotential above its lower zero current potential.
- theinput grid I8 is initially biased to such a value that the cathode-primary anode current is nearcut-oil, whereby the number of primary electrons reaching the primary anode is too small to provide any effective output current, and no current is being supplied to the coil t, or only a current that produces a magnetic field that deflects to the left the electrons emitted through the window, the tube i 0 is in its triggered-off condition, and signal impressed on the primary winding of the input transformer will not be transmitted through the tube.
- Vm ii (T) The magnitude of the magnetic field strength required to make the primary electrons follow the path 0 is given by 1.414 Vm ii (T) where m and e are the mass and the charge of an electron, V is the voltage of the primary anode and the deflector and collector electrodes, and R is the radius of the path 0.
- Fig. 6 shows the cathode-primary anode current versus current in the electromagnet 5 for a complete cycle of operation in a circuit arrangement constructed in accordance with the invention, and in which resistors 21, 28, 29 were of 4.5 megohms, 2 megohms and 1 megohm, respectively, the input grid bias was of the order of -36 volts, the deflector potential was of the order of volts, and that. of the primary anode and the collector grid was about volts.
- The'coil .5 consisted of 13,750 turns of No. 36 wire, and had a resistance of 3000 ohms; 10 milliamperes produced a field of 34 gauss at its center.
- the anode current is a fraction of a milliampere, in the specific instance, 0.65 milliampere.
- Increase of the coil current causes 'only a slight increase in the anode current until a critical coil current A (about 26 milliamperes) is reached at which the anode current jumps to 12.8' milliamperes.
- Decrease in the coil current to a second critical value B causes the tube to trigger ofl. with the primary anode current restored to its low value. It. will be noted that the anode current rises slightly as the coil current is thus decreased between A and B, and that the coil current to trigger ofi the tube is substantially less than that required to trigger it on.
- the first trigger-on or first critical point A results in a slight decrease in the anode current until a third critical coil current C (about 46 milliamperes) is reached at which the tube triggers off.
- a third critical coil current C about 46 milliamperes
- the sensitivity of the trigger control may be varied by changing the potential on the deflector electrode.
- the lower the positive potential of the deflector electrode the smaller the energizing current required in the coil 5.
- the tube was caused to trigger on initially with a current of only 9.5 milliamperes in the coil 5.
- Fig. '7 shows how the critical currents A, B, C, D for the coil current vary with variation in deflector electrode potential.
- Figs. 4 and 5 there is a residual primary anode current when the tube is in its oil condition in order that there may be, for control purposes, sufllcient primary electrons escaping through the window in the primary anode.
- the circuit arrangement of Fig. 11 enables maintaining the requisite primary electron flow for control purposes in the off condition of the tube and simultaneously a zero output current.
- the primary anode is divided into two portions 119', I9", and the input grid is also divided into a portion l8 farther removed from the anode portion l9 than another portion i8" is from the anode portion l9".
- the grid portion It being nearer to the cathode than grid portion l8", requires a lower order of negative bias to cut oil electron flow to the anode portion i9 than is required for cut-off of electron flow to the portion Id".
- the greater separation between grid portion l8 and anode portion i0 than that between the portions i8" and i9" also contributes in this respect. Therefore, when grid portion I8" is near but not quite at primary anode current cut-oil potential, grid portion I8 will be biased beyond cut-off so that, for the off condition of the tube, primary electrons do not flow to the anode portion 19' and no output current evidences itself in the output transformer.
- Anode portion IE it will be observed, is connected within the tube to the collector grid.
- Fig. 12 is a plan view of a possible electrode arrangement for the tube I 0' of Fig. 11.
- the input grid and the primary anode have been described and shown as, altered in configuration, the input grid could be left the same as in Fig. 5 and only the primary anode changed, the spacings of the primary anode sections from the grid being appropriately chosen.
- Fig. 8 illustrates. the relation to the electrodes of tube ill of the magnetic lines of force providedby the magnetic yoke and coil 5' of Fig. 2.
- the yoke was of iron
- the coil consisted of 19,000 turns of No. 36
- the direction of current flow in the coil 5' may be such as to produce magnetic lines of force in either direction across the gap between yoke ends 6, and yet enable substantially the same oif and on cycle to be obtained.
- the arrangement of Fig. 2 provides the equivalent of an ordinary relay. As with the arrangement of Fig. 1, the sensitivity of the trigger control is dependent on the potential at which the deflector electrode is maintained.
- Fig. 9 shows a family of coil current-deflector potential curves for the arrangement of Fig. 2,.in which the primary anode and collector grid of tube l0 were at volts and the input grid was at a potential of 22.5 volts.
- Fig. 10 shows a closed ring pulse counting circuit comprising a plurality of stages of the magnetically controlled trigger vacuum tubes of this invention.
- Each tube lib-I05 is similar to tube [0 of Fig. 4.
- the magnetic field producing coil for each tube comprises two separate windings L1, L2, the windings L1 being connected in parallel across the terminals 50 on which are impressed the pulses to be counted, and each winding L2 being connected in a primary anode potential lead'from the high potential terminal of source 25', the winding L2 or a particular tube being connected in the primary anode potential supply lead of the preceding tube in the ring.
- Biasing potential for the input-grids of the tubes is provided by source 3!; the collector grid directly, and the auxiliary anode, through a resistor 21' are connected to the potential source 25', while the deflector electrodes are connected to an intermediate point on the source 25.
- the resistors 21', 28', 29' are proportioned so that the auxiliary anodes normal potential, i. e., when the tube is in oil condition, is at least above the lower I already been fired or is in its on condition, its
- cathode-primary anode current flows through the In winding of tube lllz, which produces a magnetic field in tube I02 of a strength substantially less than that required to trigger it on.
- each winding L1 produces a magnetic field in its associated tube that is of strength substantially less than that required to trigger on the tube, but which, in the case of tube I02, supplements the field already provided by its winding L2 sufficiently to cause tube I02 to trigger on. This primes the succeeding tube I03 since the primary anode current of tube Illa fiows through the L2 winding of tube l0: and provides the initial magnetic field for the latter.
- the preceding tube 101 triggers ofi, each L2 winding being of sumcient resistance to cause such change in the primary anode potential of a tube as it triggers on that, acting through the coupling condenser, in the present instance C2, it momentarily reduces the primary anode'potential of the preceding tube to such a value that insufiicient primary electrons reach theauxiliary anode thereof to maintain the auxiliary anode at its floating potential.
- the fall of the auxiliary anode potential to its normal potential causes the input grid to reduce still further the fiow of primary electrons in tube I01 and, in the absence of energizing current in both of the windings L1, L2 associated with tube (01 the latter remains triggered oii.
- successivecurrent pulses are impressed through terminals 50, the tubes fire in succession around the ring, the register R in the primary anode lead for tube Ills registering every fifth pulse received.
- Fig. 13 shows an oscillation generating circuit incorporating the magnetically controlled trigger tube of this invention.
- the control coil 60 is connected in the cathode-primary anode circuit with a frequency-determining condenser 10 in parallel with it.
- the resistors ll, l8, 19 are proportioned so that the auxiliary anode is at least at a potential higher than the first zero current potential of its voltage-current characteristic.'
- the input grid is biased to near primary anode current cut-ofi.
- the deflector electrode is at a positive potential that, in the absence of, or with a minimum, current in the coil 60, permits the escaped primary electrons to deflect to and bombard the auxiliary anode whereby the latter rises to its stable floating potential and drives the input grid in a positive direction to trigger on the primary anode current. If it is assumed that the circuit has just been connected, and that the tube has triggered on, the primary anode current flow in coil 60 produces a magnetic field that, with proper polarity, deflects the escaped primary electrons away from the auxiliary anode, whereasoaoia mary electrons away from the auxiliary anode.
- the escaped primary electrons again bombard the tions generated in the coil may be induced.
- an electronic device comprising a primary electron source, a primary anode containing an aperture through which some of the primary electrons originating in said source may escape, a control electrode between said source and anode, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons, said auxiliary anode being positioned out of the direct path of said escaped electrons, and an auxiliary electrode positioned in the path of said escaped electrons, means to maintain said auxiliary electrode at a potential positive with respect to said source such that escaped electrons are drawn to said auxiliary electrode, means for biasing said control grid negatively with respect to said cathode such that only a portion of the electrons originating in said source have access to said primary anode, means connecting said auxiliary anode and said control electrode so that increase in the auxiliary anode potential with bombardment by escaped electrons decreases the negative bias on said control electrode, and electromagnetic means to deflect the escaped electrons from their path to said auxiliary electrode and onto said auxiliary an
- an electronic device comprising a primary electron source, a pair of primary electron targets, one of said targets having an aperture for the escape of some primary electrons therethrough, a control electrode between said source and said targets and having separate portions to control the electron flow between said source and each target, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons, and an auxiliary electrode in the normal path of said escaped electrons to attract such escaped electrons thereto, means to bias the control electrode such that some electron flow occurs between said source and said apertured target and said auxiliary electrode but none occurs between said source and the second target, means connecting said auxiliary anode and said control electrode so that change of potential on said auxiliary anode upon bombardment and cessation of bombardment thereof with primary electrons changes the potential of said control electrode in the same relative direction as that of the auxiliary anode, and means to deflect the escaped electrons from their normal path to said auxiliary electrode and onto said auxiliary anode, whereby. if the escaped electrons are
- said escaped electrons a control electrode between said source and said primary anode, and an auxiliary electrode in the path of the escaped electrons and normally deflecting the escaped electrons onto the auxiliary anode, means to bias said control electrode so that a small number only of primary electrons flow to said primary anode and escape through the aperture therein, means connecting said auxiliary anode and said control electrode so that when primary electrons bombard the auxiliary anode and its potential rises, the bias on the control electrode is overcome suiiiciently to enable a large number of primary electrons to flow to said primary anode, and means connected to said source and said primary anode to produce, when said large number of electrons flow between said source and said primary anode, a magnetic field for deflecting the escaped primary electrons away from said auxiliary anode.
- an electronic device comprising a primary electron source, a primary anode containing an aperture through which some of the primary electrons originating in said source may escape, a control electrode between said source and anode, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons, said auxiliary anode being positioned out of the direct path of the escaped electrons, and an auxiliary electrode positioned in the path of said escaped electrons, means to maintain said auxiliary electrode at a potential positive with respect to said source such that escaped electrons are drawn to said auxiliary electrode, a load circuit connected to said primary anode electrons in ratio greater than unity when bombarded with escaped 'primaryelectrons and an auxiliary electrode in the normal path ofsaid escaped electronsto-attract such escaped electrons thereto, means to bias the control electrode 7 such that some electron flow .occurs between said source and said apertured target and said auxiliary electrode but none occurs between said source and the second target, means J
- an electronic device comprising a primary electron source, a pair of primary electron targets, one of said targets having an aperture for the escape of some primary electrons therethrough, a control electrode between said source and said targets to control the electron flow between said source and each target, an auxiliary anode to emit secondary electrons from their normal path to said auxiliary electrode and onto said auxiliary anode, whereby, if the escaped electrons are so deflected, the change in auxiliary anode potential alters the. control electrode potential sufllciently to establish electron flow between said source and said second target.
- an electronic device comprising a primary'electron source, a pair of primary electron targets, one of said targets having an aperture for the escape of some primary electrons therethrough, a control electrode between said source and said targets to control the electron fiow between said source and each target, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons and an auxiliary electrode in the normal path of said escaped electrons to attract such escaped electrons thereto, means for impressing a signal wave between said control electrode and said primary source, a utilization circuit connected to said primary source and the second of said targets, means to bias the control electrode such that some electron flow occurs between said primary source and said apertured target and said auxiliary electrode but none occurs between said source and the second target, means connecting said auxiliary anode and said control electrode so that change of potential on said auxiilary anode upon bombardment and cessation of bombardment thereof with prising the primary source, the control electrode and said second target.
- the means connected to said source and said primary 10 anode to produce the magnetic field for deflecting the escaped primary electrons away from said auxiliary anode includes a coil to be traversed by electrons that flow between said source and said primary anode, a frequency-determining condenser connected in parallel with saidcoil, and a load circuit coupled to said coil.
- said electromagnetic means comprises a, coil which when traversed by current produces magnetic flux in a direction parallel to the axis of the device.
- said electromagnetic means comprises a coil which when traversed by current produces magnetic iiux in a direction parallel to the axis of said device, current flow in one direction only through the coil being effective to produce flux deflecting the escaped electrons onto the auxiliary anode.
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Description
SECONDARY ELECTRON EMITTER 3 Sheets-Sheet 1 F IG. 5
COLLECTOR GRID oEFLA'c TOR PRIMARY A NUDE A. M. SKELLETT ELECTRON DISCHARGE DEVICE CIRCUITS Filed Oct. 23, 1941 Jan. 19, W43.
INVENTOR AMSKELLETT l I 4O CURRENT IN CO/L- MlLL/AMPERES A TTORNEY Jan. 19, 1943. A. M. SKELLETT ELECTRON DISCHARGE DEVICE CIRCUITS Filed Oct. 25, 1941 5 Shets-Sheet 2 FIG. 7
0 O 0 O o o O 3 2 I. 2 3
MAGNE TIC LINES OF FORCE T U ML TL MM 5 M A Y B m CA an F D F W M M M0 0 o o l O m 0 M O m o w ATTOR v Jan. 19, 1943. A. M. SKELLETT ELECTRON DISCHARGE DEVICE CIRCUITS Filed Oct. 23, 1941 5 Sheets-Sheet 5 FIG. /0
CONTROL INPUT l ili L;
FIG.
lNl ENTOP By AM. SKELLETT ATTOR EV atented Jan. 19, 1943 ELECTN DISCHARGE DEVICE CIRCUITS Albert M. Skellett, Madison, N. 1., assignor to Bell 7 Telephone Labo ratorles,
Incorporated, New
Yoi-k, N. Y., a corporation of New York Application October 23,1941, Serial No. 416,155
13 Claims.
' tions of the subject-matter of my United States Patent 2,293,177, oi August 18, 1942, for Electron discharge device circuits.
An object of the invention is. to improve the means and method of regulating or controlling the on and oil properties or conditions of a trigger device comprising a vacuum tube of the secondary electron emission type.
A feature of the invention comprises controlling the operating condition of such a trigger device by means of a magnetic field, the lines of force of which may extend either parallel to or perpendicular to the ans of the device.
A more complete understanding of the invention will be obtained from the detailed description that follows, read with reference to the appended drawings, wherein:
Figs. 1, 2 and 3 illustrate arrangements for associating a magnetic field with an electronic device or vacuum tube;
Fig. 4 shows a circuit arrangement in accord- I ance with the invention in which a secondary electron emission type vacumn tube has an electromagnet associated with it, as in the arrangement of Fig. l, to provide a magnetic field parallel to or along the axis of the tube;
Fig. 5 illustrates the electrode arrangement in the tube of Fig. 4 and will be referred to inadescribing the actionof the magnetic field on the primary electrons emitted through the window or aperture in the primary anode;
Fig. 6 is a typical operating characteristic of the tube, being a plot of magnetizing current in the magnetic field producing coil of Figs. 1 and 4 versus cathode-primary anode current, evidencing two critical primary anode current "oil" and two critical primary anode current "on" values of magnetizing current for a given set of potential conditions on the tube electrodes;
Fig. 7 shows a family of curves illustrating how these critical off and on" magnetizing current values are aflected by variation in deflector electrode potential;
Fig. 8 is a schematic of a vacuum tube such Fig. 9 shows a family of curves illustrating how current in the coil vary with variation in deflector electrode potential, and with the direction of flow of the magnetizing current through the coil 'or electromagnet of Figs. 2 and 5;
Fig. 10 shows a closed ring pulse counting circuit embodying the magnetically controlled secondary electron emitter vacuum trigger tube of this invention;
Figs. 11 and 12 show a modification of the circult and electrode arrangements of Figs. 4 and 5; and
Fig. 13 shows an oscillation generating circuit incorporating a trigger device in accordance with this invention.
In my aforementioned Patent 2,293,177 is disclosed a vacuum tube having a trigger characteristic, i. e., it may be substantially instantaneously energized or deenergized dependent on its initial condition. For a detailed description of the construction and of circuit applications of this tube reference may be had to the aforementioned patent, but, in general, the tube comprises a cathode;an input control grid; aprimary anode having an aperture or window therein for the passage or escape therethrough of primary electrons originating at the cathode; a secondary electron emitting electrode or auxiliary anode having an emission ratio greater than unity; a collector'electrode or grid for collecting secondary electrons released when primary electronsbombard the auxiliary electrode; and a deflector electrode for collecting cathode particles that may be released from said cathode, and for bending or deflecting from their normal paths primary electrons that pass outwardly through the aperture in the primary anode so that they may impinge on or bombard the secondary electron emitting surface of the auxiliary electrode; all of the electrodes being supported in an evacuated'envelope. The auxiliary anode has a floating characteristic, and as a result of a suitable connection to the input grid may be utilized with the latter to trigger the tube on, subsequent to which the tube may be used as a modulator, amplifier, oscillator or detector.
Instead of utilizing 9, signal impulse to the input grid and/or the auxiliary anode to trigger the tube on or ofl as in the aforementioned patcut, the trigger action, in accordance with this invention, may be effected by magnetic or electromagnetic means, the presence or absence and the density of magnetic flux parallel or perpendicular to the axis of the tube determining whether the primary electron stream is incident on the auxiliary anode and whether the latter is at its flotation potential and the input grid at a potential substantially above cathode-primary anode current cut-H.
Figs. 1, 2 and 3 illustrate how magnetic fluxproducing means may be associated with a vacuum tube It of the general type disclosed in my aforementioned patent. In Fig. 1, an electromagnet 5, shown in cross section, surrounds the tube, and when energizing current flows in the electromagnet it produces magnetic flux in a direction parallel to the axis of the tube. In Fig. 2, the electromagnet ii surrounds a yoke ll of magnetic material between whose ends 0 the tube is located. In Fig. 3, the.ei ectromagnet comprises a pair of coils t", each shown in cross section, between which the tube is positioned. With the arrangements of Figs. 2 and 3, magnetic flux may be produced that is perpendicular to the axis of the tube and at an azimuthal angle dependent on the locationof the yoke ends or of the coils 5" with respect to the tube.
A circuit arrangement in accordance with the invention is shown by Fig. 4. The vacuum tube l0 comprises a primary electron source or cathode ll, which may be indirectly heated; an input grid it; a primary anode i9 having an aperture or window 30 for the passage therethrough of some primary electrons; a deflector electrode 20; a secondary electron collector electrode or grid 2i; and a secondary electron emitting electrode or auxiliary anode 22, which maybe similar to the correspondingly identified elements of Figs. 1, 2 and 3 of my aforementioned patent, but with the electrode arrangement of Fig. 3A of that patent. A source 2% of potential is connected between the grounded cathode and the primary anode, in circuit with the primary winding of an output transformer 28. The collector grid is connected directly to the high potential terminal of source 2%, and the auxiliary anode is connected thereto through the resistor 21. The deflector electrode 20 is maintained at a positive potential which may he of the same order as that of the collector grid and primary anode, or less. The auxiliary anode is connected to the cathode through series-connected resistors 20, 20 and the source it of biasing potential for the grid l8, and to the latter through the tap or slide 32 engaging with resistor 20 and the secondary winding of input transformer 33. The resistors 27, 28, 20 are proportioned so that the auxiliary anode, in the absence. 'of primary electrons incident thereon, is at apotential above its lower zero current potential.
With appropriate positive potential onthe deflector electrode and no energizing or flux-producing current flowing in the coil 5, the primary electrons that are propelled from the cathode and through the window 80 in the primary anode are caused to follow the path 17, Fig. 5 with none having access to the auxiliary anode. With current flow in one direction through the coil 5, the electrons are deflected to the left or caused to follow the path a, Fig. 5; with current flow in the opposite or reverse direction through the coil 5, the primary electrons are deflected to the right or cause to follow the path 0, Fig. 5. If it is assumed that theinput grid I8 is initially biased to such a value that the cathode-primary anode current is nearcut-oil, whereby the number of primary electrons reaching the primary anode is too small to provide any effective output current, and no current is being supplied to the coil t, or only a current that produces a magnetic field that deflects to the left the electrons emitted through the window, the tube i 0 is in its triggered-off condition, and signal impressed on the primary winding of the input transformer will not be transmitted through the tube. If, now, current is caused to flow in the coil in such direction as to produce a magnetic field that deiiects the primary electron stream along path 0, secondary electrons are caused to be emitted from the anode t2 and the latter rapidly rises in potential. As it increases to its stable floating potential, the bias on the grid i8 is decreased and the grid is driven sumciently in the positive direction so that substantial flow of electrons to the primary anode results. After the tube is thus triggered on, its cathode-input gridprimary anode structure may be utilized, for example, to amplify or to detect the signal wave impressed on the cathode-input grid circuit throughthe transformer 33. The tube may be triggered off by removing, or reversing the direction of, the magnetic field. The described combination of coil, tube and circuit has properties the equivalent of those of a polarized relay, as well as those of a conventional vacuum tube.
The magnitude of the magnetic field strength required to make the primary electrons follow the path 0 is given by 1.414 Vm ii (T) where m and e are the mass and the charge of an electron, V is the voltage of the primary anode and the deflector and collector electrodes, and R is the radius of the path 0.
Fig. 6 shows the cathode-primary anode current versus current in the electromagnet 5 for a complete cycle of operation in a circuit arrangement constructed in accordance with the invention, and in which resistors 21, 28, 29 were of 4.5 megohms, 2 megohms and 1 megohm, respectively, the input grid bias was of the order of -36 volts, the deflector potential was of the order of volts, and that. of the primary anode and the collector grid was about volts. The'coil .5 consisted of 13,750 turns of No. 36 wire, and had a resistance of 3000 ohms; 10 milliamperes produced a field of 34 gauss at its center. In the off" condition of the tube, that is, with no current in the coil it to produce a magnetic field of correct polarity, the anode current is a fraction of a milliampere, in the specific instance, 0.65 milliampere. Increase of the coil current causes 'only a slight increase in the anode current until a critical coil current A (about 26 milliamperes) is reached at which the anode current jumps to 12.8' milliamperes. Decrease in the coil current to a second critical value B (about 12 milliamperes) causes the tube to trigger ofl. with the primary anode current restored to its low value. It. will be noted that the anode current rises slightly as the coil current is thus decreased between A and B, and that the coil current to trigger ofi the tube is substantially less than that required to trigger it on.
. When the tube triggers on, the potential of the auxiliary anode rises and this helps to hold the electrons over on to it. This insures a high order of stability to the .tube in its oil and in its on condition.
Once the tube has been triggered on, increase of the coil current above: the first trigger-on or first critical point A results in a slight decrease in the anode current until a third critical coil current C (about 46 milliamperes) is reached at which the tube triggers off. This results because the primary electron stream is deflected or bent to such an extent that the primary electrons no longer strike the auxiliary anode; the latter ceases to emit secondaries and decreases in potential to its original condition, and the efiect on the grid 18 of the negative bias from source it is no longer compensated. After the tube has been triggered ofl in this manner, an appreciable reduction in the magnitude of the coil current below the upper trigger-off point C is necessary before the tube again triggers on at a fourth critical coil current D as a result of the primary electrons again bombarding the auxiliary anode. In the particular case, this occurred at about 34 milliamperes, at which the anode current rose to about 12 milliamperes. Further reduction in the coil current causes the anode current to increase slightly until coil current B is again reached at which the tube triggers off.
The sensitivity of the trigger control may be varied by changing the potential on the deflector electrode. In general, the lower the positive potential of the deflector electrode the smaller the energizing current required in the coil 5. For example, for potential conditions otherwise the same as those under which the characteristic of Fig. 6 was obtained but with the deflector electrade at +45 volts, the tube was caused to trigger on initially with a current of only 9.5 milliamperes in the coil 5. Fig. '7 shows how the critical currents A, B, C, D for the coil current vary with variation in deflector electrode potential.
These characteristic curves were obtained with the primary anode and the collector grid at +180 volts, and with the input grid biased to -22.5 volts. Thepositive and negative signs on the coil current scale indicate the direction of current flow through the coil, i. e., positive currents produce a magnetic field whose tendency is to deflect the primary electron stream toward the path 0, negative currents produce a magnetic field of reversed polarity from that of the field produced by the positive currents and whose tendency is to deflect the primary electron stream toward path a.
With the arrangement of Figs. 4 and 5 there is a residual primary anode current when the tube is in its oil condition in order that there may be, for control purposes, sufllcient primary electrons escaping through the window in the primary anode. The circuit arrangement of Fig. 11 enables maintaining the requisite primary electron flow for control purposes in the off condition of the tube and simultaneously a zero output current. The primary anode is divided into two portions 119', I9", and the input grid is also divided into a portion l8 farther removed from the anode portion l9 than another portion i8" is from the anode portion l9". The grid portion It, being nearer to the cathode than grid portion l8", requires a lower order of negative bias to cut oil electron flow to the anode portion i9 than is required for cut-off of electron flow to the portion Id". The greater separation between grid portion l8 and anode portion i0 than that between the portions i8" and i9" also contributes in this respect. Therefore, when grid portion I8" is near but not quite at primary anode current cut-oil potential, grid portion I8 will be biased beyond cut-off so that, for the off condition of the tube, primary electrons do not flow to the anode portion 19' and no output current evidences itself in the output transformer. Anode portion IE", it will be observed, is connected within the tube to the collector grid. Fig. 12 is a plan view of a possible electrode arrangement for the tube I 0' of Fig. 11. Although in'this modification of the invention both the input grid and the primary anode have been described and shown as, altered in configuration, the input grid could be left the same as in Fig. 5 and only the primary anode changed, the spacings of the primary anode sections from the grid being appropriately chosen.
The specific description hereinabove has been with respect to a control coil that produces a magnetic field substantially parallel to the axis of the tube. The arrangements of Figs. 2 and 3 enable magnetic control of the primary electron stream by means of amagnetic field extending perpendicular to the axis of the tube. Fig. 8 illustrates. the relation to the electrodes of tube ill of the magnetic lines of force providedby the magnetic yoke and coil 5' of Fig. 2. In a specific embodiment of the invention, the yoke was of iron, the coil consisted of 19,000 turns of No. 36
wire and had a resistance of 3,660 ohms. The gap between the faces of yoke ends 6 was about 1 inches and 10 milliamperes of direct current in the coil 5' produced a fleld of 50 gauss at the center of the gap. The direction of the magnetic field with respect to the electrodes has been determined to be ,somewhat critical, best results being obtained when the direction of the field in the gap was set at an angle of 4.0 degrees with respect to the plane of the collector grid, although deviations of the order of a few degrees from this condition could be tolerated. A typical cycle of on and off operation for this arrangement would be similar to that shown in Fig. 6 for the control coil arrangement of Fig. 1. With the arrangement of Fig. 2 and Fig. 8, however, the direction of current flow in the coil 5' may be such as to produce magnetic lines of force in either direction across the gap between yoke ends 6, and yet enable substantially the same oif and on cycle to be obtained. The arrangement of Fig. 2 provides the equivalent of an ordinary relay. As with the arrangement of Fig. 1, the sensitivity of the trigger control is dependent on the potential at which the deflector electrode is maintained. Fig. 9 shows a family of coil current-deflector potential curves for the arrangement of Fig. 2,.in which the primary anode and collector grid of tube l0 were at volts and the input grid was at a potential of 22.5 volts.
Fig. 10 shows a closed ring pulse counting circuit comprising a plurality of stages of the magnetically controlled trigger vacuum tubes of this invention. Each tube lib-I05 is similar to tube [0 of Fig. 4. The magnetic field producing coil for each tube comprises two separate windings L1, L2, the windings L1 being connected in parallel across the terminals 50 on which are impressed the pulses to be counted, and each winding L2 being connected in a primary anode potential lead'from the high potential terminal of source 25', the winding L2 or a particular tube being connected in the primary anode potential supply lead of the preceding tube in the ring. Biasing potential for the input-grids of the tubes is provided by source 3!; the collector grid directly, and the auxiliary anode, through a resistor 21' are connected to the potential source 25', while the deflector electrodes are connected to an intermediate point on the source 25. The resistors 21', 28', 29' are proportioned so that the auxiliary anodes normal potential, i. e., when the tube is in oil condition, is at least above the lower I already been fired or is in its on condition, its
cathode-primary anode current flows through the In winding of tube lllz, which produces a magnetic field in tube I02 of a strength substantially less than that required to trigger it on. When a ourrent pulse is impressed on the terminals 50, each winding L1 produces a magnetic field in its associated tube that is of strength substantially less than that required to trigger on the tube, but which, in the case of tube I02, supplements the field already provided by its winding L2 sufficiently to cause tube I02 to trigger on. This primes the succeeding tube I03 since the primary anode current of tube Illa fiows through the L2 winding of tube l0: and provides the initial magnetic field for the latter. Simultaneously, the preceding tube 101 triggers ofi, each L2 winding being of sumcient resistance to cause such change in the primary anode potential of a tube as it triggers on that, acting through the coupling condenser, in the present instance C2, it momentarily reduces the primary anode'potential of the preceding tube to such a value that insufiicient primary electrons reach theauxiliary anode thereof to maintain the auxiliary anode at its floating potential. The fall of the auxiliary anode potential to its normal potential causes the input grid to reduce still further the fiow of primary electrons in tube I01 and, in the absence of energizing current in both of the windings L1, L2 associated with tube (01 the latter remains triggered oii. As successivecurrent pulses are impressed through terminals 50, the tubes fire in succession around the ring, the register R in the primary anode lead for tube Ills registering every fifth pulse received.
Fig. 13 shows an oscillation generating circuit incorporating the magnetically controlled trigger tube of this invention. The control coil 60 is connected in the cathode-primary anode circuit with a frequency-determining condenser 10 in parallel with it. The resistors ll, l8, 19 are proportioned so that the auxiliary anode is at least at a potential higher than the first zero current potential of its voltage-current characteristic.' The input grid is biased to near primary anode current cut-ofi. The deflector electrode is at a positive potential that, in the absence of, or with a minimum, current in the coil 60, permits the escaped primary electrons to deflect to and bombard the auxiliary anode whereby the latter rises to its stable floating potential and drives the input grid in a positive direction to trigger on the primary anode current. If it is assumed that the circuit has just been connected, and that the tube has triggered on, the primary anode current flow in coil 60 produces a magnetic field that, with proper polarity, deflects the escaped primary electrons away from the auxiliary anode, whereasoaoia mary electrons away from the auxiliary anode.
The escaped primary electrons again bombard the tions generated in the coil may be induced.
in coil 80 for supply through the terminals fill to an appropriate load. In addition to its tuning function, condenser assures that the primary anode potential does not fall to too low a value when the tube triggers on. Subject-matter not specifically claimed herein is being claimed in a divisional application, Serial No. 456,875, filed September 1, 1942, for Electron dscharge device circuits.
Although this invention has been disclosed with reference to certain specific embodiments, it is to be understood that the invention is not limited thereto, but is of a scope evidenced by the appended claims.
What is claimed is:
1. In combination, an electronic device comprising a primary electron source, a primary anode containing an aperture through which some of the primary electrons originating in said source may escape, a control electrode between said source and anode, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons, said auxiliary anode being positioned out of the direct path of said escaped electrons, and an auxiliary electrode positioned in the path of said escaped electrons, means to maintain said auxiliary electrode at a potential positive with respect to said source such that escaped electrons are drawn to said auxiliary electrode, means for biasing said control grid negatively with respect to said cathode such that only a portion of the electrons originating in said source have access to said primary anode, means connecting said auxiliary anode and said control electrode so that increase in the auxiliary anode potential with bombardment by escaped electrons decreases the negative bias on said control electrode, and electromagnetic means to deflect the escaped electrons from their path to said auxiliary electrode and onto said auxiliary anode.
2. In combination, an electronic device comprising a primary electron source, a pair of primary electron targets, one of said targets having an aperture for the escape of some primary electrons therethrough, a control electrode between said source and said targets and having separate portions to control the electron flow between said source and each target, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons, and an auxiliary electrode in the normal path of said escaped electrons to attract such escaped electrons thereto, means to bias the control electrode such that some electron flow occurs between said source and said apertured target and said auxiliary electrode but none occurs between said source and the second target, means connecting said auxiliary anode and said control electrode so that change of potential on said auxiliary anode upon bombardment and cessation of bombardment thereof with primary electrons changes the potential of said control electrode in the same relative direction as that of the auxiliary anode, and means to deflect the escaped electrons from their normal path to said auxiliary electrode and onto said auxiliary anode, whereby. if the escaped electrons are so deflected, the
said escaped electrons, a control electrode between said source and said primary anode, and an auxiliary electrode in the path of the escaped electrons and normally deflecting the escaped electrons onto the auxiliary anode, means to bias said control electrode so that a small number only of primary electrons flow to said primary anode and escape through the aperture therein, means connecting said auxiliary anode and said control electrode so that when primary electrons bombard the auxiliary anode and its potential rises, the bias on the control electrode is overcome suiiiciently to enable a large number of primary electrons to flow to said primary anode, and means connected to said source and said primary anode to produce, when said large number of electrons flow between said source and said primary anode, a magnetic field for deflecting the escaped primary electrons away from said auxiliary anode.
4. In'combination, an electronic device comprising a primary electron source, a primary anode containing an aperture through which some of the primary electrons originating in said source may escape, a control electrode between said source and anode, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons, said auxiliary anode being positioned out of the direct path of the escaped electrons, and an auxiliary electrode positioned in the path of said escaped electrons, means to maintain said auxiliary electrode at a potential positive with respect to said source such that escaped electrons are drawn to said auxiliary electrode, a load circuit connected to said primary anode electrons in ratio greater than unity when bombarded with escaped 'primaryelectrons and an auxiliary electrode in the normal path ofsaid escaped electronsto-attract such escaped electrons thereto, means to bias the control electrode 7 such that some electron flow .occurs between said source and said apertured target and said auxiliary electrode but none occurs between said source and the second target, means Jconnecting said auxiliary anode and said control electrode so that change of potential on said auxiliary anode upon bombardment and cessation of bombardment thereof with primary electrons ,changes the potential of saidcontrol electrode in the same relative direction as that of the auxiliary anode, and means to deflect the escaped and said primary source, a signal input circuit connected to said control electrode and said primary source, means for biasing said control electrode negatively with respect to ,said source such that only a portion of the electrons originating at said source have access to said primary anode whereby substantially none of the signal that may appear in said input circuit is reproduced in said load circuit, means connecting said auxiliary anode and said control electrode so that increase in the auxiliary anode potential with bombardment by escaped electrons decreases the negative bias on said control electrode such that a substantial primary electron flow to said primary anode is established whereby the signal appearing in the input circuit is reproduced 'in the load circuit, and electromagnetic means to deflect the escape electrons from their path to said auxiliary electrode and onto said auxiliary anode. 5. In combination, an electronic device comprising a primary electron source, a pair of primary electron targets, one of said targets having an aperture for the escape of some primary electrons therethrough, a control electrode between said source and said targets to control the electron flow between said source and each target, an auxiliary anode to emit secondary electrons from their normal path to said auxiliary electrode and onto said auxiliary anode, whereby, if the escaped electrons are so deflected, the change in auxiliary anode potential alters the. control electrode potential sufllciently to establish electron flow between said source and said second target.
6. The combination of claim 5 in which an electric wave input circuit is connected to said control electrode and said primary source, and aload circuit is connected to said primary source and said second target.
7.-In combination, an electronic device comprising a primary'electron source, a pair of primary electron targets, one of said targets having an aperture for the escape of some primary electrons therethrough, a control electrode between said source and said targets to control the electron fiow between said source and each target, an auxiliary anode to emit secondary electrons in ratio greater than unity when bombarded with escaped primary electrons and an auxiliary electrode in the normal path of said escaped electrons to attract such escaped electrons thereto, means for impressing a signal wave between said control electrode and said primary source, a utilization circuit connected to said primary source and the second of said targets, means to bias the control electrode such that some electron flow occurs between said primary source and said apertured target and said auxiliary electrode but none occurs between said source and the second target, means connecting said auxiliary anode and said control electrode so that change of potential on said auxiilary anode upon bombardment and cessation of bombardment thereof with prising the primary source, the control electrode and said second target.
8. The combination of claim 3 in which the means connected to said primary source and said primary anode to produce the magnetic field for deflecting the escaped primary electrons away from the auxiliary anode includes a coil to be traversed by electrons flowing between said source and said primary anode.
9. The combination of claim 3 in which the said coil.
10. The combination of claim 3 in which the means connected to said source and said primary 10 anode to produce the magnetic field for deflecting the escaped primary electrons away from said auxiliary anode includes a coil to be traversed by electrons that flow between said source and said primary anode, a frequency-determining condenser connected in parallel with saidcoil, and a load circuit coupled to said coil.
11. The combination of claim 1 in which a signal wave input circuit is connected to said primary source and said control electrode and a load circuit is connected to said primary source and said primary anode.
12. The combination of claim 1 in which said electromagnetic means comprises a, coil which when traversed by current produces magnetic flux in a direction parallel to the axis of the device.
13. The combination of claim 1 in which said electromagnetic means comprises a coil which when traversed by current produces magnetic iiux in a direction parallel to the axis of said device, current flow in one direction only through the coil being effective to produce flux deflecting the escaped electrons onto the auxiliary anode.
ALBERT M. SKELLET'I.
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US416155A US2309019A (en) | 1941-10-23 | 1941-10-23 | Electron discharge device circuits |
US456875A US2329792A (en) | 1941-10-23 | 1942-09-01 | Electron discharge device circuit |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US416155A US2309019A (en) | 1941-10-23 | 1941-10-23 | Electron discharge device circuits |
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US2309019A true US2309019A (en) | 1943-01-19 |
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Application Number | Title | Priority Date | Filing Date |
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US416155A Expired - Lifetime US2309019A (en) | 1941-10-23 | 1941-10-23 | Electron discharge device circuits |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2512984A (en) * | 1948-09-01 | 1950-06-27 | Stromberg Carlson Co | Secondary emission tube ring circuit |
US2547142A (en) * | 1948-11-27 | 1951-04-03 | Bell Telephone Labor Inc | Secondary emission amplifier |
US2662177A (en) * | 1947-04-21 | 1953-12-08 | Hartford Nat Bank & Trust Co | Switching system using secondary emission type beam tubes |
US2845534A (en) * | 1945-05-15 | 1958-07-29 | Conrad H Hoeppner | Secondary emission trigger circuit |
-
1941
- 1941-10-23 US US416155A patent/US2309019A/en not_active Expired - Lifetime
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2845534A (en) * | 1945-05-15 | 1958-07-29 | Conrad H Hoeppner | Secondary emission trigger circuit |
US2662177A (en) * | 1947-04-21 | 1953-12-08 | Hartford Nat Bank & Trust Co | Switching system using secondary emission type beam tubes |
US2512984A (en) * | 1948-09-01 | 1950-06-27 | Stromberg Carlson Co | Secondary emission tube ring circuit |
US2547142A (en) * | 1948-11-27 | 1951-04-03 | Bell Telephone Labor Inc | Secondary emission amplifier |
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