US2604606A - Target for storage tubes - Google Patents

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US2604606A
US2604606A US122657A US12265749A US2604606A US 2604606 A US2604606 A US 2604606A US 122657 A US122657 A US 122657A US 12265749 A US12265749 A US 12265749A US 2604606 A US2604606 A US 2604606A
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storage
eyelet
target
eyelets
electrons
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Jan A Rajchman
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RCA Corp
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RCA Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J31/00Cathode ray tubes; Electron beam tubes
    • H01J31/08Cathode ray tubes; Electron beam tubes having a screen on or from which an image or pattern is formed, picked up, converted, or stored
    • H01J31/58Tubes for storage of image or information pattern or for conversion of definition of television or like images, i.e. having electrical input and electrical output
    • H01J31/66Tubes for storage of image or information pattern or for conversion of definition of television or like images, i.e. having electrical input and electrical output having means for allowing all but selected cross-section elements of a homogeneous electron beam to reach corresponding elements of the screen, e.g. selectron

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  • This invention relates to electron discharge devices of the type in which an elemental area of a target electrode is charged to one of two predetermined potentials and stores that potential whereby it constitutes a memory element.
  • this invention relates to an improved target electrode construction and means for indicating the condition of the memory element of said target.
  • I disclose a grid control type of memory target wherein a first target provides a memory and control function, and a second target provides for the reading or indicating function. This is accomplished by providing holes in the dielectric surface which constitutes each memory element with p nding holes in the signal plate through tion to provide an which electrons may pass to impinge upon a selected area of a second target to cause-fluorescence. Alternatively the electrons which pass through the first'taiget are passed into an area where three focussing electrodes are biased to cause the electrons to impinge on a wire. This sets up a current in the wire which constitutes a reading current.
  • the grid control type of targets shown in my above mentioned copending application all had storage elements which were in the form of a wire screen, a'hollow truncated cone or a hollow cylindrical eyelet, all insulatingly mounted in a metal capacity plate or writing plate. In view of the necessity for drilling the writing'plate, then insulating the drilled holes, then fastening the various storage elements to the insulation, the manufacture of these targets proved difiicult and expensive. Also, although these previous grid control types of targets operated satisfactorily, upon investigation it was found that they were not as efiicient as they could be because the id control efiect interfered to a certain extent with the storage effect.
  • a target assembly consisting of a collector electrode which consists of two metal plates in intimate contact and havin aligned perforations of different diameters, a plurality of storage eyelets insulatingly supported between two mica sheets, a perforated writing plate, both writing plate and collector electrode being capacitively associated with the plurality of eyelets and both having their perforations aligned with the pluralityof storageeyelets.
  • a reading plate also with aligned perforations, is spaced from the writing plate.
  • a Faraday'cage is spaced from the reading plate and the two sides parallel to the reading plate have perforations aligned with those of the reading plate.
  • :A glass plate with a fiuorescent-and-secondary electronemlttingcoating. on one'side has the coated side pressed against the perforated wall of the'Faraday cage'which, is further away from Inside the Faraday cage are the perforation to be'shielded from direct emission from the cathodes. Any electrons which are passedthrough the eyelets strike the fluorescent'screen and cause; fluorescencev as well as This secondary emission is picked up by the reading wires as a reading current.
  • Figure 2 isan enlarged sectional view of the ifirst 'targetassembly which is a portion of an embodiment of my invention
  • Figure-3 is a curve of the current voltage characteristicof a single storage eyelet element
  • an electron discharge storage device which includes the target which is an embodiment of my present invention, has
  • cathodes l2 an outer glass envelope ill, a plurality of elongated cathodes l2 of rectangular cross section which are coextensive with a set of separately insulated vertical selecting wires [4 or bars of square cross section.
  • the cathodes [2 are interposed between and are alternate with the vertical selecting bars I4.
  • a plurality of separately -insulated vertical selecting wires I6 or bars are spaced on 4 either side from and parallel with the plane formed by the cathodes and horizontal selecting bars.
  • Figure 2 is an enlarged cross sectional view of the first target electrode and also represents the electron paths for two potential conditions of the storage area of the target.
  • the first target electrode consists of a collector electrode it having as many perforations as 7 forations and a collector spacer 22 which has the larger perforations.
  • Two perforated plates made of an insulating material 24, such as mica, insulatingly support between them a plurality of storage eyelets 25.
  • the storage eyelets 26 are made from a metal having good secondary emission and not evaporating too easily. I prefer to use steel, with a plating of nickel, or beryllium.
  • the storage eyelet is constructed with a collar 42 so that it may be easily dropped into one of the insulating plates and retained by placing the other insulating plate over the storage eyelet so that it bears on the collar. This assembly may then be easily fastened together at the four corners or any other convenient location.
  • the perforations of the insulating plates are placed so that the eyelets 26 are retained in alignment with the collector electrode perforations and the windows formed by the selecting bars.
  • the perforations in the collector spacer 22 are of such size as to permit it to be brought against the insulating plate which holds the storage eyelet without touching the eyelets.
  • the thickness of the collector spacer is such as to support the collector mask 20 proximal to the storage eyelets 26.
  • Each perforation in the collector mask is slightly smaller than the conical opening 46 at the head of each of the storage eyelets.
  • the collector electrode l8 thus effectively masks the insulating plates 26 from the contamination eifects of the cathode or any other heated electrode and thus reduces any ohmic leakage which may occur along the surface of the insulating plates 24.
  • a bias or writing plate 28 is the last part of the first target assembly. It is made of metal and also has perforations large enough so that it can fit over and proximal to the tails of the storage eyelets 26 and against. the insulating sheet 24 between the storage eyelets.
  • the thickness of the writing plate 28 is such as to cause it to extend slightly beyond the tail of the eyelet and to have a reasonably large .capacity with all the eyelets since the writing technique with this type of target requires pulsing the bias plate to change the eyelet potential. Too small a capacity would require an excessively high pulse amplitude.
  • the second target electrode structure consists of another metal plate spaced from and parallel to the writing plate. This is known as the reading plate 3
  • a Faraday screen 32 or cage Spaced from the reading plate is a Faraday screen 32 or cage. It is made in the form of a rectangular metal box having two sides parallel and substantially coextensive with the reading plate 30. These two parallel sides have perforations which are aligned with the reading plate perforations and the storage eyelets. Extending through the Faraday cage and positioned between the rows of perforations are a number of reading wires 34. These wires are connected together and a single shielded lead 36 is brought therefrom external to the tube. 38 having on one side a fluorescent and secondary emissive coating 49, such as willemite, is placed with its coated side against the outside of the perforated wall of the Faraday cage which is further from the reading plate 39. Thus, any electrons which are passed by the eyelets into the Faraday cage 32, strike the fluorescent coating 40 and the secondary electrons which are emitted therefrom are picked up by the reading wires 34 and detected externally as a reading current. 5
  • the collector electrode 58 is connected externally by means of the collector lead 23, the writing plate 28 is connected externally by means of the writing plate lead 29.
  • the reading plate 30 is connected externally by means of its lead 31 and the reading wires are connected externally by means of the shielded lead 36.
  • Lead I5 is representative of an externally connecting lead to a vertical selecting wire and lead I! is repre sentative of an externally connecting lead to a horizontal selecting wire.
  • the secondary emission is suppressed because there is a lack of collecting field for the low energy secondary electrons so that the current again becomes zero at a point P3 (slightly more positive than the collector potential) in the absence of all leakage currents.
  • P3 point
  • the secondary emission is suppressed completely and the current to the eyelet is negative again (points such as P4 on the curve).
  • the electron current to it in a steady state must be zero, because the action of the electron current on the eyelet is such as to cause it to accumulate charges and thus to change in potential until it reaches the point at which no more electron cur-rent flows.
  • the floating eyelet can therefore be at one of the three values PI, P2 or P3 for which the electron current is zero. In practice, however, only points PI and P3 are stable ones. Any slight disturbances, such as a very slight ohmic current due to leakage on the surface of the mica, is sufficient to move the eyelet potential away from point P2.
  • the present eyelet is therefore made deep and to have a somewhat constricted neck portion so that no negative retarding field can. reach that portion of the storage eyelet which is subjected to electron bombardment to diminish its efficiency.
  • the diameter of the tail of the eyelet must be chosen sufliciently large so that when the eyelet is at its most positive stable potential (or collector potential) it has enough influence to overcome the negative field region caused by the negative bias on the writing plate and thus permit the passage therethrough of electrons.
  • the eyelet head has a frusto-conical shape in order that the electron paths be as perpendicular to the surface at the opening 44 of the eyelet as possible for the negative condition of the storage eyelet.
  • the electron paths for the positive and negative conditions of the eyelet may be seen in Figure 2.
  • the eyelet When the eyelet is positive the electrons pass through it substantially in the path shown.
  • the eyelet When the eyelet is negative most of the electrons are turned back to the collector. A few that get past the collar opening are repelled by the negative field from the writing plate. Electrons succeed best in overcoming a potential hill when they are moving straight in line with the steepest gradient because they are not deflected sideways. An angle of 25 degrees was found to be optimum for the geometry of the .particular tube described here.
  • the wall area of the hole in the collar of the eyelet must be small enough so that the per- .centage of electron current striking there without .producing secondary electrons may be as small as possible. On the other hand it must be large enough to let through'an appreciable electron reading current. .A ratio of diameters of 3:1 of the collector mask hole to the eyelet collar hole was found to be satisfactory. The ratio of diameters of the eyelet head to the collector mask hole was established in the ratio of 5:3-in order to reduce the diverging electron effect mentioned above. The combination of eyelet head diameter and theproper cone angle brings about a reasonably large negative loop .in the voltage current characteristic curve of the eyelet (Fig. 3) The smallness of the eyelet hole and the proximity to the collector plate brings about a good secondary emission collecting field insuring a reasonably large positive loop in the voltage-current characteristic curve (Fig. 3).
  • the electrical circuit connections for one half of the tube illustrated in Fig. l is shown schematically in Fig. 4. Since, as seen in Figure 1, the tube is symmetrical about its cathode plane, it will be understood that this system of connections is utilizable for both halves of the tube.
  • the cathodes 12 are preferably connected to ground while thecollector electrode I8, the writ ing 28 and reading plates 30, the Faraday shield 32 and the reading wires 34 are all connected to a suitable source of D.-C. potential 46 the approximate values of which are indicated in Fig. 4. This source may, for example, be provided by a battery and a resistance voltage divider.
  • the control circuit for applying potentials for opening or closing the windows formed by the horizontal and vertical selecting bars is repre sented by the selection circuit device 48.
  • a pulse for conditioning the storage eyelet selected is applied to the terminal 50 which is capacitively coupled to the writing plate by means of a com denser.
  • a pulse to permitreading is. applied to the reading plate through the terminal 52 which is capacitively coupled to the reading plates by means of a, condenser. Electrical output is taken from the output terminals 5 8 which are connected across the load impedance.
  • the Faraday cage 32 provides efiicient shielding for the reading wires 34 against any stray capacity influence.
  • the reading wires and Faraday cage may be omitted and thecondition of the target elements may be read visually by observing the presence or absence of fluorescence when a single eyelet is selected.
  • the Faraday cage and fluorescent screen may be omitted, and the reading plate may be made without apertures so that when a single eyelet is selected, depending upon its potential, electrons may or may not strike the reading plate.
  • An electron discharge device having a source of electrons, a storage target, and means to direct said electrons from said source to selected areas of said stora e target, said storage target including a secondary emissive storage eyelet at each of said selected areas, and insulating means supporting and spacing all of the storage eyelets.
  • An electron discharge device having a source of electrons, a storage target, and means to direct said electrons from said source to selected areas of said storage target, said storage target including a secondary emissive storage eyelet at each of said selected areas and a pair of perforated insulating plates supporting and spacing all of the storage eyelets.
  • An electron discharge device having a source of electrons, a storage target, and means to direct said electrons from said source to selected areas of said storage target, said storage target including a secondary emissive storage eyelet at each of said selected areas, a pair of perforated insulating plates supporting and spacing all of the storage eyelets and a collector electrode between said insulating plates and said source of electrons, said collector electrode shielding said insulating plates from said source of electrons and having perforations aligned with each of the eyelets.
  • An electron discharge device as recited in claim 3 wherein there is included in addition a metal writing plate having perforations aligned with said eyelets, said writing plate'belng capacitatlvely disposed with reference to all said eyelets.
  • collector electrode comprises two perforated metal plates in contact with each other, one of said plates having perforations of sufficient size to be interposed between each of said storage eyelets and having a sufficient thickness to space the other of said plates over each of said eyelets, both said plates serving to prevent the passage of electrons between said eyelets.
  • a grid action storage target for an electron memory tube comprising a plurality of secondary emissive storage eyelets each having head and tail ends, a pair of perforated insulating plates supporting and spacing each of the eyelets between said head and tail ends, a collector electrode having perforations aligned with each of said storage eyelets and having a portion interposed between each of the head ends of the eyelets, and a metal writing plate having perforations aligned with each of said eyelets, said perforations being of a size to permit said metal writing plate to be interposed between the tail ends of said eyelets and to be capacitively associated with said eyelets.
  • a storage eyelet for a grid action storage target made of a secondary emissive metal and having a head portion, a tail portion and a collar portion by means of which said eyelet is supported, the opening of said head portion of said eyelet being of a frusto-conical shape, said tail portion opening being of a cylindrical shape and a narow cylindrical shaped throat portion joining the head and tail portion openings.
  • An electron discharge device having a source of electrons, a first grid action target including a plurality of storage eyelets, means to direct said electrons from said source to selected ones of said eyelets, and a second reading target, said second reading target including a transparent dielectric base having a fluorescent and second electron emissive coating thereon and a plurality of interconnected reading wires biased to capture the emitted secondary electrons.
  • An electron discharge device having a source of electrons, a first grid action target having a plurality of perforations aligned with said storage area perforations, a Faraday cage having two walls parallel to said reading electrode, said Walls having perforations aligned with said reading electrode perforations, a plurality of parallel reading wires positioned within said Faraday cage and between said perforations to be shielded from said grid action target, and a translucent dielectric plate having one side coated with a fluorescent and secondary emissive material, said dielectric plate being positioned with its coated side adjacent a perforated wall of said Faraday cage to be bombarded by electrons which pass through said cage from said grid action target to emit secondary electrons responsive thereto which are collected by said reading wires.
  • First and second targets for an electron memory tube said first target comprising a plurality of secondary emissive storage eyelets each having head and tail ends, a pair of perforated insulating plates supporting and spacing each of the eyelets between said head and tail ends, a collector electrode having perforations aligned with each of said storage eyelets and having a portion interposed between each of the head ends of the eyelets, and a metal writing plate having perforations aligned with each of said eyelets, said perforations being of a size to permit said metal writing plate to be interposed between the tail ends of said eyelets and to be capacitively associated with said eyelets, said second target comprising a metal plate reading electrode spaced from said writing plate and having a plurality of perforations aligned with said eyelet, a Faraday cage having two walls parallel to said reading electrode, said walls having perforations aligned with said reading electrode perforations, a plurality of parallel reading wires positioned within said Faraday cage and between said perforations to be shielded from said grid

Description

July 1952 J- A. RAJCHMAN TARGET FOR STORAGE TUBES 3 Sheets-Sheet 1 Filed pct. 15. 1949 SSSQSSQQ lNVNTOR Jan/1. [Pay ATTOR N EY I I l I l I I I l ll rlll II III &
July 22, 1952 J. A. RAJCHMAN 2,604,606,
TARGET FOR STORAGE TUBES Filed Oct. 15. 1949 s Sheets-Sheet 2 I ATTRNE y 1952 J. A. RAJCHMAN TARGET FOR STORAGE TUBES 3 Sheets-Sheet 3 Filed Oct. 15, 1949 0 1 Mi MW W% /J\ m H fl a? k W a. u n k 4 H w y A o 440 m m .3, k r z 1 Patented July 22, 1952 TARGET FOR STORAGE TUBES Jan A. Bajchman, Princeton, N. J., assignor to Radio Corporation of America, a corporation of Delaware Application October 15, 1949, Serial No. 122,657
This invention relates to electron discharge devices of the type in which an elemental area of a target electrode is charged to one of two predetermined potentials and stores that potential whereby it constitutes a memory element. In particular, this invention relates to an improved target electrode construction and means for indicating the condition of the memory element of said target.
In my copending applications Ser. No. 665,031 filed April 26, 1946 for an Electron Discharge Device, now Patent No. 2,494,670, issued January 17, 1950, and Ser. No. 118,527, filed September 29, 1949 also for an Electron Discharge Device, electron discharge devices of the area selection and storage or memory type have been described. Briefly, these consist of a source of electrons, a horizontal and a vertical selecting grid network for directing electrons from the source to a selected elemental area of a target electrode. Other Well known types of storage tubes use electrostatic deflection plates or deflection coils for directing electrons from the source to a desired target area.
In my copending application for an Electron Storage Device With Grid Control Action, Serial No. 722,194, filed January 15, 1947, now Patent No. 2,513,743 issued July 4, 1950, I show various types of target constructions suitable for use in a memory type of tube. Memory tube targets in general have their surface areas divided into small areas eachof which is capacitively coupled to a common signal plate. These small areas then comprise small condensers in which information is stored by the presence or absence of a charge. By conditioning successively selected ones of these small condensers to either have a charge or not, the device may be made Claims. (Cl. 315-12) to store intelligent information. The device finds its greatest utility in connection with computing systems utilizing the system of counting wherein one of two stable conditions represents a one and the other of the two stable conditions represents a zero, or any other system of counting in M which the numbers are represented by coded combinations of the two conditions.
In my copending application for an Electron Storage Device with Grid Control Action, I disclose a grid control type of memory target wherein a first target provides a memory and control function, and a second target provides for the reading or indicating function. This is accomplished by providing holes in the dielectric surface which constitutes each memory element with p nding holes in the signal plate through tion to provide an which electrons may pass to impinge upon a selected area of a second target to cause-fluorescence. Alternatively the electrons which pass through the first'taiget are passed into an area where three focussing electrodes are biased to cause the electrons to impinge on a wire. This sets up a current in the wire which constitutes a reading current.
Whether or not electrons may pass through the hole in the storage element of the first target depends'upon the potential of that particular element.
The grid control type of targets shown in my above mentioned copending application all had storage elements which were in the form of a wire screen, a'hollow truncated cone or a hollow cylindrical eyelet, all insulatingly mounted in a metal capacity plate or writing plate. In view of the necessity for drilling the writing'plate, then insulating the drilled holes, then fastening the various storage elements to the insulation, the manufacture of these targets proved difiicult and expensive. Also, although these previous grid control types of targets operated satisfactorily, upon investigation it was found that they were not as efiicient as they could be because the id control efiect interfered to a certain extent with the storage effect. In other words, it can be shown that at each of the eyelets or memory elements there'is established aregion which even though bombarded with primary electrons will not permit the escape of secondaryelectrons. The extent of this retarding field depends upon the potential at which the eyelet is established. It represents an area of wasted power asjar as results frombombardment by electrons from the cathode are concerned.
In view of the insertion of the memory eyelets in the metal writing plate, as stated above, there is. some ohmic leakage between memory eyelets at a higher potential and those at a lower potential. Some cross-talk linkage also exists, that is, some secondary electrons which are emitted from the eyelets are collected by adjacent eyelets instead of by the collector plate.
It is an object of my present invention to provide an improved target electrode construction which is simpler to manufacture than hereto- It is still another object of my-present invention to provide an improved target electrode construction'for an electron storage tube which is more efiicient than heretofore.
It is still another object of my presentinvenimproved target electrode conthe reading plate. 'reading wires which are .positioned between secondary electron emission.
.fine aplurality of windows. to the selecting bars defining a, window deter- .7
struction for an electron storage tube which can simultaneously provide a visual and electrical in dication of the condition of the memory elements of the target.
These and other objects of my invention are achieved by making a target assembly consisting of a collector electrode which consists of two metal plates in intimate contact and havin aligned perforations of different diameters, a plurality of storage eyelets insulatingly supported between two mica sheets, a perforated writing plate, both writing plate and collector electrode being capacitively associated with the plurality of eyelets and both having their perforations aligned with the pluralityof storageeyelets. A reading plate, also with aligned perforations, is spaced from the writing plate. ,A Faraday'cage is spaced from the reading plate and the two sides parallel to the reading plate have perforations aligned with those of the reading plate.
:A: glass plate with a fiuorescent-and-secondary electronemlttingcoating. on one'side has the coated side pressed against the perforated wall of the'Faraday cage'which, is further away from Inside the Faraday cage are the perforation to be'shielded from direct emission from the cathodes. Any electrons which are passedthrough the eyelets strike the fluorescent'screen and cause; fluorescencev as well as This secondary emission is picked up by the reading wires as a reading current.
'The: novel features of myinvention, as well as: the invention itself, both as to its organization and method of operation; will best be understood. from the'following description when read in connection with, the accompanying drawing in'which' Figure 1pis, anaxial sectional view of an .elec- .tron dischar e stora e tube Which includes a :targetwhich is an embodiment of my present invention,
Figure 2 isan enlarged sectional view of the ifirst 'targetassembly which is a portion of an embodiment of my invention,
Figure-3 is a curve of the current voltage characteristicof a single storage eyelet element, and
ber 30, 1949.
Referring to Figure 1, an electron discharge storage device which includes the target which is an embodiment of my present invention, has
an outer glass envelope ill, a plurality of elongated cathodes l2 of rectangular cross section which are coextensive with a set of separately insulated vertical selecting wires [4 or bars of square cross section. The cathodes [2 are interposed between and are alternate with the vertical selecting bars I4. A plurality of separately -insulated vertical selecting wires I6 or bars are spaced on 4 either side from and parallel with the plane formed by the cathodes and horizontal selecting bars.
It will be readily appreciated that when viewed in a plane perpendicular to the planeof the horizontal and vertical selecting bars, these bars de- The bias applied individual selecting bar wires have been described and claimed in my copending application ser. No. 702,775, filed October 11, 1946, now Patent No. 2,558,460, issued June 26, 1951, and in the application of. George W. Brown, Ser. No. 694,041, filed August 30, 1946, now Patent No. 2,519,172, issued August 15, 1950.
It is to be understood that the particular arrangement employed for generating and directing electrons toward a selected elemental area is not, as such, a part of my present invention. Any arrangement for this purpose may be employed.
On-either outer side of the horizontal selecting bars is a first target electrode. Figure 2 is an enlarged cross sectional view of the first target electrode and also represents the electron paths for two potential conditions of the storage area of the target.
The first target electrode consists of a collector electrode it having as many perforations as 7 forations and a collector spacer 22 which has the larger perforations. Two perforated plates made of an insulating material 24, such as mica, insulatingly support between them a plurality of storage eyelets 25. The storage eyelets 26 are made from a metal having good secondary emission and not evaporating too easily. I prefer to use steel, with a plating of nickel, or beryllium. The storage eyelet is constructed with a collar 42 so that it may be easily dropped into one of the insulating plates and retained by placing the other insulating plate over the storage eyelet so that it bears on the collar. This assembly may then be easily fastened together at the four corners or any other convenient location. The perforations of the insulating plates are placed so that the eyelets 26 are retained in alignment with the collector electrode perforations and the windows formed by the selecting bars. The perforations in the collector spacer 22 are of such size as to permit it to be brought against the insulating plate which holds the storage eyelet without touching the eyelets. The thickness of the collector spacer is such as to support the collector mask 20 proximal to the storage eyelets 26. Each perforation in the collector mask is slightly smaller than the conical opening 46 at the head of each of the storage eyelets. The collector electrode l8 thus effectively masks the insulating plates 26 from the contamination eifects of the cathode or any other heated electrode and thus reduces any ohmic leakage which may occur along the surface of the insulating plates 24.
A bias or writing plate 28 is the last part of the first target assembly. It is made of metal and also has perforations large enough so that it can fit over and proximal to the tails of the storage eyelets 26 and against. the insulating sheet 24 between the storage eyelets. The thickness of the writing plate 28 is such as to cause it to extend slightly beyond the tail of the eyelet and to have a reasonably large .capacity with all the eyelets since the writing technique with this type of target requires pulsing the bias plate to change the eyelet potential. Too small a capacity would require an excessively high pulse amplitude.
The second target electrode structure consists of another metal plate spaced from and parallel to the writing plate. This is known as the reading plate 3|] and also has perforations which are aligned with the storage eyelets.
Spaced from the reading plate is a Faraday screen 32 or cage. It is made in the form of a rectangular metal box having two sides parallel and substantially coextensive with the reading plate 30. These two parallel sides have perforations which are aligned with the reading plate perforations and the storage eyelets. Extending through the Faraday cage and positioned between the rows of perforations are a number of reading wires 34. These wires are connected together and a single shielded lead 36 is brought therefrom external to the tube. 38 having on one side a fluorescent and secondary emissive coating 49, such as willemite, is placed with its coated side against the outside of the perforated wall of the Faraday cage which is further from the reading plate 39. Thus, any electrons which are passed by the eyelets into the Faraday cage 32, strike the fluorescent coating 40 and the secondary electrons which are emitted therefrom are picked up by the reading wires 34 and detected externally as a reading current. 5
Leads connecting the various portions of the target external to the tube are shown connected to. only one of the two target assemblies shown in Figure 1. Connections to the other target assembly will be understood although not shown.
The collector electrode 58 is connected externally by means of the collector lead 23, the writing plate 28 is connected externally by means of the writing plate lead 29. The reading plate 30 is connected externally by means of its lead 31 and the reading wires are connected externally by means of the shielded lead 36. Lead I5 is representative of an externally connecting lead to a vertical selecting wire and lead I! is repre sentative of an externally connecting lead to a horizontal selecting wire.
The operation of this device including the selection of the individual storage elements, the release of secondary electrons by the storage elements and the method of conditioning the storage element to one or the other of two stable conditions is as described in my copending application for an Electron Discharge Tube, Ser. No. 118,758, filed September 30, 1949, as well as the earlier applications referred to above and need not be described herein in greater detail.
The principle of operation of the storage eyelet is briefly set forth below for the purposes of a clearer exposition of one of the features of my invention. Referring to Figure 3 wherein is shown a curve of the electron current to the eyelet as a function of its potential, when the potential of the eyelet is more negative than the cathode (point P0), no electron current can reach it. When the eyelet is approximately at cathode potential electrons begin to strike it and some negative current gets to the eyelet (region P! to P2 of the curve). As the eyelet potential becomes more positive, the secondary emission becomes greater than the primary emission and A translucent plate a positive current flows from the eyelet (region P2P3 of the curve). As the eyelet reaches the potential of the collector electrode the secondary emission is suppressed because there is a lack of collecting field for the low energy secondary electrons so that the current again becomes zero at a point P3 (slightly more positive than the collector potential) in the absence of all leakage currents. For more positive values of the eyelet the secondary emission is suppressed completely and the current to the eyelet is negative again (points such as P4 on the curve).
If the eyelet is electrically floating, or connected to no lead, the electron current to it in a steady state must be zero, because the action of the electron current on the eyelet is such as to cause it to accumulate charges and thus to change in potential until it reaches the point at which no more electron cur-rent flows. The floating eyelet can therefore be at one of the three values PI, P2 or P3 for which the electron current is zero. In practice, however, only points PI and P3 are stable ones. Any slight disturbances, such as a very slight ohmic current due to leakage on the surface of the mica, is sufficient to move the eyelet potential away from point P2.
In order to place a storage eyelet into one or the other of the two stable potential conditions the electron current flow is directed only toward that single storage eyelet and none other. A similar procedure is followed for reading the potential condition of the eyelet. In order to assist the storage eyelet in properly repelling electrons, when it is near the cathode potential, so that none may get through the eyelet and cause a false reading during reading and quiescent periods of the tube, a negative bias potential is at all times placed on the writing plate 22 except when it is used for writing. The effect of this negative bias potential, in previous types of storage targets, was to create an area in the storage eyelet where the field potential distribution was such as to prevent the emission of secondary electrons from a considerable portion of the storage eyelet under electron bombardment, regardless of its potential. The present eyelet is therefore made deep and to have a somewhat constricted neck portion so that no negative retarding field can. reach that portion of the storage eyelet which is subjected to electron bombardment to diminish its efficiency. The diameter of the tail of the eyelet, however, must be chosen sufliciently large so that when the eyelet is at its most positive stable potential (or collector potential) it has enough influence to overcome the negative field region caused by the negative bias on the writing plate and thus permit the passage therethrough of electrons.
The eyelet head has a frusto-conical shape in order that the electron paths be as perpendicular to the surface at the opening 44 of the eyelet as possible for the negative condition of the storage eyelet. The electron paths for the positive and negative conditions of the eyelet may be seen in Figure 2. When the eyelet is positive the electrons pass through it substantially in the path shown. When the eyelet is negative most of the electrons are turned back to the collector. A few that get past the collar opening are repelled by the negative field from the writing plate. Electrons succeed best in overcoming a potential hill when they are moving straight in line with the steepest gradient because they are not deflected sideways. An angle of 25 degrees was found to be optimum for the geometry of the .particular tube described here.
Some strong side deflections are unavoidable at the edges of the cone. These strongly diverging electrons must be stopped from going into adjacent storage eyelets (crosstalk). This is done by the walls of the holes of the collector spacer plate 22 as shown in Figure 2.
The wall area of the hole in the collar of the eyelet must be small enough so that the per- .centage of electron current striking there without .producing secondary electrons may be as small as possible. On the other hand it must be large enough to let through'an appreciable electron reading current. .A ratio of diameters of 3:1 of the collector mask hole to the eyelet collar hole was found to be satisfactory. The ratio of diameters of the eyelet head to the collector mask hole was established in the ratio of 5:3-in order to reduce the diverging electron effect mentioned above. The combination of eyelet head diameter and theproper cone angle brings about a reasonably large negative loop .in the voltage current characteristic curve of the eyelet (Fig. 3) The smallness of the eyelet hole and the proximity to the collector plate brings about a good secondary emission collecting field insuring a reasonably large positive loop in the voltage-current characteristic curve (Fig. 3).
The electrical circuit connections for one half of the tube illustrated in Fig. l is shown schematically in Fig. 4. Since, as seen in Figure 1, the tube is symmetrical about its cathode plane, it will be understood that this system of connections is utilizable for both halves of the tube. The cathodes 12 are preferably connected to ground while thecollector electrode I8, the writ ing 28 and reading plates 30, the Faraday shield 32 and the reading wires 34 are all connected to a suitable source of D.-C. potential 46 the approximate values of which are indicated in Fig. 4. This source may, for example, be provided by a battery and a resistance voltage divider. The control circuit for applying potentials for opening or closing the windows formed by the horizontal and vertical selecting bars is repre sented by the selection circuit device 48. A pulse for conditioning the storage eyelet selected is applied to the terminal 50 which is capacitively coupled to the writing plate by means of a com denser. A pulse to permitreading is. applied to the reading plate through the terminal 52 which is capacitively coupled to the reading plates by means of a, condenser. Electrical output is taken from the output terminals 5 8 which are connected across the load impedance.
In operation, when'the device is in the quiescent or standby condition all the windows are on and all the storage eyelets are subjected to electron bombardment. ukn'y storage eyelets which are in the negative condition, with the aid of the negatively biased writing plate, prevent electrons from passing therethrough. 'Any storage eyelets, which arein the positive condition, pass electrons but these are all captured -or repelled by the negatively biased reading plate 30. When it is desired to write or condition a storage eyelet, all the windows are closed except the one to the storage eyelet selected and a conditioning pulse is applied to the writing plate 28. When it is desired to read the condition of a particular eyelet 25, all the windows are closed except the one to the eyelet desired and a positive pulse is applied to the reading plate 30. This permits passage of electrons therethrough from the selected eyelet, if the eyelet is in a positive condition. These impinge on the fluorescent coating 40 through the perforation associated with that eyelet causing the coating to fluoresce at that position, thus giving a visible indication of a positive condition. Secondary electrons which are emitted by the fluorescent coating are captured by the high potential reading wires 34 and thus provide an electrical indication of a positive condition. The Faraday cage 32 provides efiicient shielding for the reading wires 34 against any stray capacity influence.
From the foregoingdescription it will be readily apparent that I have provided an improved and efilcient grid action storage target and reading target assembly for memory type electron tubes. Although the target has been described in connection with a dual channel type of target area selecting type of memory tube usingtwo targets, it may be used with any type of tube which provides the structure required to direct electrons from a source to a specific desired area of the target. Although I have shown and described but a single embodiment of my present invention it should be apparent that many changes may be made in the particular embodiment herein disclosed, and that many other embodiments are possible, all within the spirit and scope of my invention. For example, the reading wires and Faraday cage may be omitted and thecondition of the target elements may be read visually by observing the presence or absence of fluorescence when a single eyelet is selected. The Faraday cage and fluorescent screen may be omitted, and the reading plate may be made without apertures so that when a single eyelet is selected, depending upon its potential, electrons may or may not strike the reading plate. Thus,
the presence or absence of reading plate current may be used to evidence the eyelet potential condition. Therefore, I desire that the foregoing description shall be taken as illustrative and not as limiting.
What is claimed is:
1. An electron discharge device having a source of electrons, a storage target, and means to direct said electrons from said source to selected areas of said stora e target, said storage target including a secondary emissive storage eyelet at each of said selected areas, and insulating means supporting and spacing all of the storage eyelets.
2. An electron discharge device having a source of electrons, a storage target, and means to direct said electrons from said source to selected areas of said storage target, said storage target including a secondary emissive storage eyelet at each of said selected areas and a pair of perforated insulating plates supporting and spacing all of the storage eyelets.
3. An electron discharge device having a source of electrons, a storage target, and means to direct said electrons from said source to selected areas of said storage target, said storage target including a secondary emissive storage eyelet at each of said selected areas, a pair of perforated insulating plates supporting and spacing all of the storage eyelets and a collector electrode between said insulating plates and said source of electrons, said collector electrode shielding said insulating plates from said source of electrons and having perforations aligned with each of the eyelets.
4. An electron discharge device as recited in claim 3 wherein there is included in addition a metal writing plate having perforations aligned with said eyelets, said writing plate'belng capacitatlvely disposed with reference to all said eyelets.
5. An electron discharge device as recited in claim 4 wherein said collector electrode comprises two perforated metal plates in contact with each other, one of said plates having perforations of sufficient size to be interposed between each of said storage eyelets and having a sufficient thickness to space the other of said plates over each of said eyelets, both said plates serving to prevent the passage of electrons between said eyelets.
6. A grid action storage target for an electron memory tube comprising a plurality of secondary emissive storage eyelets each having head and tail ends, a pair of perforated insulating plates supporting and spacing each of the eyelets between said head and tail ends, a collector electrode having perforations aligned with each of said storage eyelets and having a portion interposed between each of the head ends of the eyelets, and a metal writing plate having perforations aligned with each of said eyelets, said perforations being of a size to permit said metal writing plate to be interposed between the tail ends of said eyelets and to be capacitively associated with said eyelets.
7. A storage eyelet for a grid action storage target made of a secondary emissive metal and having a head portion, a tail portion and a collar portion by means of which said eyelet is supported, the opening of said head portion of said eyelet being of a frusto-conical shape, said tail portion opening being of a cylindrical shape and a narow cylindrical shaped throat portion joining the head and tail portion openings.
8. An electron discharge device having a source of electrons, a first grid action target including a plurality of storage eyelets, means to direct said electrons from said source to selected ones of said eyelets, and a second reading target, said second reading target including a transparent dielectric base having a fluorescent and second electron emissive coating thereon and a plurality of interconnected reading wires biased to capture the emitted secondary electrons.
9. An electron discharge device having a source of electrons, a first grid action target having a plurality of perforations aligned with said storage area perforations, a Faraday cage having two walls parallel to said reading electrode, said Walls having perforations aligned with said reading electrode perforations, a plurality of parallel reading wires positioned within said Faraday cage and between said perforations to be shielded from said grid action target, and a translucent dielectric plate having one side coated with a fluorescent and secondary emissive material, said dielectric plate being positioned with its coated side adjacent a perforated wall of said Faraday cage to be bombarded by electrons which pass through said cage from said grid action target to emit secondary electrons responsive thereto which are collected by said reading wires.
10. First and second targets for an electron memory tube, said first target comprising a plurality of secondary emissive storage eyelets each having head and tail ends, a pair of perforated insulating plates supporting and spacing each of the eyelets between said head and tail ends, a collector electrode having perforations aligned with each of said storage eyelets and having a portion interposed between each of the head ends of the eyelets, and a metal writing plate having perforations aligned with each of said eyelets, said perforations being of a size to permit said metal writing plate to be interposed between the tail ends of said eyelets and to be capacitively associated with said eyelets, said second target comprising a metal plate reading electrode spaced from said writing plate and having a plurality of perforations aligned with said eyelet, a Faraday cage having two walls parallel to said reading electrode, said walls having perforations aligned with said reading electrode perforations, a plurality of parallel reading wires positioned within said Faraday cage and between said perforations to be shielded from said grid action target, and a translucent dielectric plate having one side coated with a fluorescent and secondary emissive material, said dielectric plate being positioned with its coated side adjacent a perforated wall of said Faraday cage to be bombarded by electrons which pass through said cage from said grid action target and to emit secondary electrons responsive thereto which are collected by said reading wires.
JAN A. RAJCHMAN.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 2,172,738 Levin Sept. 12, 1939 2,291,577 Farnsworth July 28, 1942 2,416,720 Teal Mar. 4, 1947 2,423,124 Teal July 1, 1947 FOREIGN PATENTS Number Country Date 539,496 Great Britain Apr. 1, 1940
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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2738436A (en) * 1952-09-02 1956-03-13 Chromatic Television Lab Inc Electrode structure
US2761089A (en) * 1952-01-03 1956-08-28 Hughes Aircraft Co Half-tone storage tubes
US2819419A (en) * 1954-04-23 1958-01-07 Ibm Target structure for barrier grid storage tube
US2847610A (en) * 1952-08-27 1958-08-12 Rca Corp Direct-view electrical storage tube and erasing system therefor
US2888602A (en) * 1953-02-27 1959-05-26 Ericsson Telefon Ab L M Method for reading of information stored in electronic storage tubes
US3622828A (en) * 1969-12-01 1971-11-23 Us Army Flat display tube with addressable cathode

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2172738A (en) * 1936-02-03 1939-09-12 Cathode ray tube
GB539496A (en) * 1939-04-03 1941-09-12 Mullard Radio Valve Co Ltd Improvements in or relating to mosaic electrodes for television transmitting tubes
US2291577A (en) * 1939-04-05 1942-07-28 Farnsworth Television & Radio Image amplifier
US2416720A (en) * 1943-01-30 1947-03-04 Bell Telephone Labor Inc Electrooptical device
US2423124A (en) * 1943-01-30 1947-07-01 Bell Telephone Labor Inc Electro-optical device

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2172738A (en) * 1936-02-03 1939-09-12 Cathode ray tube
GB539496A (en) * 1939-04-03 1941-09-12 Mullard Radio Valve Co Ltd Improvements in or relating to mosaic electrodes for television transmitting tubes
US2291577A (en) * 1939-04-05 1942-07-28 Farnsworth Television & Radio Image amplifier
US2416720A (en) * 1943-01-30 1947-03-04 Bell Telephone Labor Inc Electrooptical device
US2423124A (en) * 1943-01-30 1947-07-01 Bell Telephone Labor Inc Electro-optical device

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2761089A (en) * 1952-01-03 1956-08-28 Hughes Aircraft Co Half-tone storage tubes
US2847610A (en) * 1952-08-27 1958-08-12 Rca Corp Direct-view electrical storage tube and erasing system therefor
US2738436A (en) * 1952-09-02 1956-03-13 Chromatic Television Lab Inc Electrode structure
US2888602A (en) * 1953-02-27 1959-05-26 Ericsson Telefon Ab L M Method for reading of information stored in electronic storage tubes
US2819419A (en) * 1954-04-23 1958-01-07 Ibm Target structure for barrier grid storage tube
US3622828A (en) * 1969-12-01 1971-11-23 Us Army Flat display tube with addressable cathode

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