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US3531675A - Cathode ray storage tube having a target dielectric with collector electrodes extending therethrough - Google Patents

Cathode ray storage tube having a target dielectric with collector electrodes extending therethrough Download PDF

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US3531675A
US3531675A US619904A US3531675DA US3531675A US 3531675 A US3531675 A US 3531675A US 619904 A US619904 A US 619904A US 3531675D A US3531675D A US 3531675DA US 3531675 A US3531675 A US 3531675A
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target
collector electrodes
electrode
electrons
cathode ray
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Roger A Frankland
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Tektronix Inc
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J29/00Details of cathode-ray tubes or of electron-beam tubes of the types covered by group H01J31/00
    • H01J29/02Electrodes; Screens; Mounting, supporting, spacing or insulating thereof
    • H01J29/10Screens on or from which an image or pattern is formed, picked up, converted or stored
    • H01J29/36Photoelectric screens; Charge-storage screens
    • H01J29/39Charge-storage screens
    • H01J29/41Charge-storage screens using secondary emission, e.g. for supericonoscope

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  • FIG. 2 68 (PRIOR ART) ROGER A. FRANKLAND lNVE/VTOR B) BUCKHORN, BLORE, KLAROU/ST 8 SPAR/(MAN ATTORNEYS p Y R. A. FRANKLAND CATHQDE RAY STORAGE TUBE HAVING A TARGET DIELECTRIC WITH COLLECTQR ELECTRODES EXTENDING THERETHROUGH Filed Feb. 28, '1967' v 2 Sheets-Sheet 2 FIG. 3
  • a cathode ray storage tube provided with a storage target having a multiplicity of collector electrodes extending through the storage targets dielectric layer. These collector electrodes act to collect secondary electrons and control the electric field configuration near the surface of the storage target for the prevention of trace shadowing.
  • the present invention relates to cathode ray storage tubes, and particularly to cathode ray storage tubes providing improved storage accuracy.
  • a type of cathode ray storage tube includes electron beam generating means and one or more flood electron sources directed toward a storage target structure.
  • the electron beam writes and sometimes detects information on the target surface and the flood electrons are employed for retaining selected areas of the target at one of two stable potentials. In areas where the electron beam has not written, such areas are retained at the negative potential of the flood electrons. However, areas of the target struck by the electron beam become positive due to secondary emission from the target.
  • the flood electrons act to maintain these areas in a positive state inasmuch as the flood electrons are attracted to these areas and given higher velocity causing continued emission of secondary electrons.
  • collector electrode means are generally employed for collecting secondary electrons, such electrode means being suitably maintained at approximately the same potential as a storage target electrode included at the back of the storage target.
  • the target electrode itself acts as a collector electrode, and the dielectric or phosphor layer on the surface of the target electrode is sufliciently thin and porous so that secondary electrons may pass therethrough to the target electrode.
  • other collector electrodes in the form of rings or Screens are employed for the collection of secondary electrons.
  • Trace shadowing takes place as a display of information written by the electron beam is only partially illuminated by flood electrons. This shadowing, seen as an indistinct edge on the stored trace, is the result of aberrations in the electric field close to the target at locations where information has been written by the electron beam.
  • a field of this type is illustrated in FIG. 2. Flood electrons entering this field are given a transverse velocity and tend to land non-uniformly on the target with resultant trace shadowing.
  • a target is advantageously formed by a photo-etching process wherein an insulating substrate body of the target is coated with metal after which a layer of photoresist is applied.
  • the target surface is then exposed to a dot pattern mask, and the photoresist and metal between the dots is removed.
  • the surface is etched resulting in conical shaped protrusions from above a surface of the substrate body.
  • a thin transparent conductive layer is applied to this body and then a dielectric layer of phosphor material is applied which is substantially semicontinuous, except for the locations of the collector electrodes.
  • the result is a regular pattern of collector electrodes whose apices extend above the surface of the phosphor layer and which are actually a protruding extension of the thin target electrode at the rear of the phosphor material.
  • FIG. 1 is a schematic representation of a cathode ray storage tube according to the present invention
  • FIG. 2 is a cross sectional view of one prior type of storage target
  • FIG. 3 is a cross sectional view of a storage target according to the present invention.
  • FIG. 4 is a partial forward view of a storage target according to the present invention.
  • FIG. 5 is a perspective view, partially broken away and partially in cross section of a storage target according to the present invention.
  • a cathode ray storage tube inculdes a storage tube envelope 10 formed of insulating material housing a principal electron gun including a filament 12, a cathode 14 for connection to a high negative voltage source, a control grid 16 and a focusing and accelerating structure .18.
  • the electron beam produced by the principal electron gun is deflected horizontally by means of horizontal deflection plate-s 24.
  • the deflection plates are connected to conventional deflection circuits 27 for causing selective positioning of electron beam 20.
  • the beam is in general directed towards a target 46 at the opposite end of the tube.
  • the storage tube is additionally provided with one or more flood type electron guns 26 each having a cathode 28, a control grid 30 and an anode 32, and which are supported inside the envelope 10 adjacent the end of the vertical deflection plates 24 closest the target.
  • Cathodes 28 are conveniently maintained at a low voltage level, e.g. ground level, while grids 30 are suitably connected to a minus volts.
  • Lo'w velocity electrons emitted from the flood guns diverge into a wide beam which is desirably uniformly distributed towards target 46.
  • a plurality of electrodes are also located on the inner surface of envelope 10. These electrodes may be provided as spaced wall coatings of conductive material, such as silver, tin oxide, aluminum, or graphite, on the interior surface of the envelope.
  • the first electrode wall coating 34 functions primarily as a focusing electrode for the flood electrons emitted from the flood guns. It is connected to a suitable source of electrical potential, e.g. a positive 250 volts.
  • a second electrode wall coating 36 is spaced from such first electrode and electrically connected to a positive voltage, e.g. 150 volts and functions as a focusing and collimating electrode.
  • a third electrode wall coating 38 spaced from coating 36 is electrically connected to a positive voltage, e.g.
  • a fourth electrode wall coating 39 is positioned between and spaced from the wall coating 38 and the storage target 46, and is connected to a positive voltage, e.g. a positive 75 volts.
  • the wall coating 38 may function to some extent as a collector electrode to collect part of the secondary electrons emitted from the storage target 46.
  • a conventional resistive coating 40 e.g. Aquadag or similarly conductive material, is suitably provided on the interior of a portion of the envelopes neck portion and is electrically connected to an isolation shield (not shown) in the writing gun in such neck portion so that it serves as an extension of a second anode (also not shown) in such writing gun.
  • the voltages applied to electrode wall coatings 34, 36, 38, and 39 are by way of example and are suitably adjusted to provide optimum collimation of the flood electrons.
  • Storage target 46 is provided upon insulative end plate 48 and comprises a transparent storage target electrode 50 over which is disposed a dielectric 52.
  • the dielectric 52 is suitably P-l type phosphor and is at least semi-continuous.
  • Target electrode 50 is a thin deposited transparent coating such as tin oxide or the like and is suitably connected to the midpoint of a voltage divider comprising resistors 56 and 58 disposed between a plus 300 volts and ground. Resistor 56 is variable and is suitably adjusted so that a voltage of approximately plus 150 volts is applied to target electrode 50.
  • target electrode 50 may be connected to amplifying means for providing an electrical readout of information stored on the storage target.
  • Information may be written on this storage target via electron beam 20'.
  • This information may be in the form of a waveform applied to the vertical deflection plates 24 while the beam is scanned horizontally with the deflection circuits 27, or intensity information may be applied to grid 16 while the beam is scanned both vertically and horizontally by deflection circuits 27.
  • the information written on the storage target is visibly displayed through end plate 48 wherein such end plate is formed of transparent material, e.g. glass.
  • the tube potentials are adjusted such that beam 20 has a relatively high velocity for writing and is capable of producing secondary electrons when it strikes storage dielectric 52. Secondary electrons are then collected in a manner hereinafter more fully described. An elemental area of the target can be driven positive or written as a result of the secondary emission produced by electron beam '20.
  • a written area is retained at a relatively positive potential after beam 20 has passed such elemental area because of the action of flood electrons from flood guns 26.
  • Flood guns 26 produce relatively low velocity electrons which strike the target but which ordinarily have insufficient velocity for writing information.
  • these flood electrons tend to maintain such areas at a relatively low potential near the potential of the flood gun cathode. This is the stable negative potential level of the target.
  • the flood gun electrons are attracted by a positive elemental area and attain a high velocity with respect to these areas for producing continued secondary emission therefrom. Therefore these areas are maintained relatively positive or near the potential of target electrode 50. This comprises the stable positive potential level of the target.
  • the target thus has bistable properties and is capable of retaining information written thereon inasmuch as the flood beam of electrons drives target areas to one of the two stable potentials depending upon the information previously written thereon with beam 20.
  • a prior type of storage target is illustrated in cross-section including a substrate body in the form of a glass end plate 60.
  • the substrate body is provided with a target electrode 62 comprising a very thin transparent conductive coating such as tin oxide or the like.
  • a dielectric 64 Over the target electrode is disposed a dielectric 64, which is suitable as an integral layer of P1 type phosphor that may be sufliciently porous to enable secondary electrons to be transmitted therethrough and collected by the target electrode.
  • a target of this type has previously been employed in a cathode ray storage tube of the type illustrated in 'FIG. 1.
  • Region 66 on the target electrode has been written by electron beam 20 so that its voltage level has been changed from a low voltage produced by flood electrons to a higher voltage near the volt level of target electrode 62, through the process of secondary emission.
  • the electric field in front of a portion of the target in the direction of the electron sources is illustrated by equipotential electric field lines comprising the cross-section of equipotential field surfaces in front of a portion of the target. This field pattern is produced between the target and the electrode wall coatings 34, 36, 38 and 39.
  • the field voltage next to the surface of the target is at a low voltage level, e.g. 50 volts.
  • the front surface of the target is at a higher voltage, e.g.
  • FIG. 3 there is illustrated a cross section of an improved storage target in accordance with the present invention.
  • This target is employed with the cathode ray storage tube of the type illustrated in FIG. 1.
  • the target includes a substrate body which is suitably transparent and formed of insulative material, e.g. taking the form of glass end plate 70.
  • the substrate body is further provided with a target electrode 72 suitably comprising a very thin transparent deposited conductive coating such as tin oxide or the like supported on the glass end plate 70.
  • a substantially integral, or at least semi-continuous dielectric layer 74 suitably comprising a layer of phosphor, e.g. of the P-l type. This layer may be somewhat porous, like phosphor layer 64 but need not be.
  • a multiplicity of collector electrodes 76 extend from the target electrode 72 and through the substantially semi-continuous dielectric layer 74 to the side of the target nearest the electron sources. These conductive electrodes desirably protrude from the otherwise substantially planar surface of dielectric layer 74 and act as collectors for the secondary electrons generated when electron beam 20 strikes the storage target.
  • the collector electrodes extend forward about two mils from the target electrode 72, in the illustrated embodiment, and extend above the otherwise substantially planar and continuous dilectric layer 74. However, the collector electrodes 76 may protrude farther if so desired.
  • the collector electrodes in the illustrated emmodiment are approximately conical in shape with the base of each electrode being substantially coincident with the plane of target electrode 72, and with the apex of the cone extending forwardly above the level of dielectric layer 74.
  • the electrodes may take other shapes. Thus, these electrodes may be pyramidal in shape and may come to a point where they extend above the dielectric layer 74, or such point may be somewhat flattened. If desired the electrodes may alternatively by cylindrical.
  • the collector electrodes 76 are electrically connected at their base to target electrode 72.
  • the collector electrodes 76 in the illustrated embodiment are distributed over the storage target in a regular pattern with a regular spacing between electrodes as illustrated in FIG. 4.
  • the centerto-center distance between adjacent electrodes was ap proximately six mils, this being less than the approximate diameter of the electron beam 20 employed in writing on the storage target.
  • the diameter of such electron beam (or thetrace produced thereby) is about mils across from points halfway up the Gaussian distribution.
  • the distance between collector electrodes is also related to the resolution properties of the target and the cathode ray storage tube employing the same.
  • the collector electrodes six mils apart result in an approximately six mil resolution capability. For reasonable resolution it is preferred the spacing of the collector electrodes be under mils.
  • the density of collector electrodes positioned 6 mils apart on a 5" cathode ray tube results in about 300,000 of such electrodes on the storage target.
  • the electrodes may be placed closer together if desired.
  • the exposed raised collector area that is the area rising above the phosphor, comprises approximately 10 percent of the storage target surface, viewed from electron source side of the target, as thus illustrated in FIG. 4.
  • the target construction partly broken away and including a completed phosphor layer only on the left side, is illustrated in FIG. 5.
  • the target electrode illustrated in FIGS. 3, 4 and 5 has the advantage of providing a much more uniform or undistorted near field at and near the surface of the target electrode oriented towards the electron sources.
  • Illustrative equipotential lines comprising cross sections of equipotential surfaces of this field are shown in FIG. 3.
  • the field line 78 is close to the target and is at a voltage level of substantially 150 volts, this being the voltage of target electrode 72 and of the collector electrodes 76.
  • the 200 volt field line is nearly flat.
  • Region 82 illustrates the location where information has been written on the target by means of electron beam 20. In this region, the dielectric layer 74 has been raised to a potential of approximately volts, or the potential of target electrode 72, due to secondary emission from this region.
  • equipotential line 78 is closer to the dielectric layer 74 in this region.
  • the region of change of field line 78 is confined to the region between substantially adjacent electrodes 76, and close in to the target. Therefore, the more remote equipotential line 80 is substantially unaffected and remains substantially flat and undistorted as compared with the distorted field as in the case of the FIG. 2 device. Therefore, flood electrons 84 from the flood guns 26 are not substantially deflected transversely but rather proceed in a more collimated manner to the storage target.
  • dielectric layer A 74 e.g. of phosphor or the like, need not be porous and may be thicker or multi-layer without the requirement that secondary electrons be able to pass therethrough.
  • the collector electrodes 76 are suitably formed as forwardly protruding raised extensions of target electrode 72. Moreover, the substrate body 70 is suitably raised at the locations of collector electrode 76 to provide an inner body of these collector electrodes with the extension of target electrode 72 providing a conducting exterior electrically connected to the remainder of target electrode 72.
  • An exemplary method of manufacturing the storage target is described as follows. First, the glass end plate such as 70 in FIG. 3 is annealed and coated with a thin layer of nickel followed by a thin layer of gold, the nickel being used to adhere the gold to the glass end plate. The metals are suitably evaporated onto the end plate. Then a layer of photoresist material is applied over the layer of gold and the plate is baked.
  • the surface is then exposed photographically to provide a dot pattern on the metal layer having the same general configuration as the collector electrodes as illustrated in FIG. 4, but with dots somewhat larger in diameter to correspond to the base diameter of electrodes 76, e.g. about 5 mils.
  • the areas around the electrodes are illuminated and exposed, for example, using a light source and a contact negative comprising a pattern of opaque dots.
  • the photoresist is developed with the areas around the dots being dissolved.
  • the plate is then baked.
  • the NiAu layer is etched away around the dots using gold and nickel etchants in succession with an intermediate rinse. An etchant is then applied which acts to remove the glass around the dots, the latter being protected with metal.
  • a suitable etchant includes one part HF and one part dimethyl sulfoxide.
  • the surface of the glass end plate 70 is lowered around these dots by etching.
  • the etchant also has the effect of etching the glass away from underneath the exposed dots to provide conical raised protrusions 86 as illustrated in FIG. 3.
  • the glass is removed under the metal dots at the same rate as the glass is etched downwardly. A cone results, the sides of which have an approximately 45 degree slope.
  • the glass is cleaned and a thin transparent conductive coating such as tin oxide or the like is deposited thereon to form target electrode 72 as well as completing the multiplicity of collector electrodes 76.
  • the target now appears as illustrated on the right side of FIG. 5.
  • target electrode layer 72 The thickness of target electrode layer 72 is exaggerated for ease of illustration.
  • dielectric phosphor material e.g. a P-l type phosphor is cast into the etched end plate, e.g. using an Elvax binder and toluene solvent, between the collector electrodes in the form of substantially semi-continuous phosphor layer interrupted only by the collector electrodes 76.
  • the plate is baked to complete the target.
  • the completed target is illustrated on the left side of FIG. 3.
  • the forward portion of the target electrode may be eX- tended or shaped as desired to control the near field potential.
  • the target electrodes may be extended forwardly to a greater height, or the forward protruding ends of the collector electrodes may be connected with very narrow strips of aluminum or gold or the like evaporated to connect between the ends of the protruding collector electrodes.
  • the selected material should be easy to evaporate and have a sufiicient integrity to maintain its shape. In any case, it is desired that the exposed dielectric phosphor comprise the majority of the target surface and that the collector electrodes be spaced approximately as close as the desired resolution of the target.
  • the raised collectors inner body may be transparent or opaque, insulative or electrically continuous.
  • a random array rather than a regular array of collector electrodes may be fabricated. For example, in one instance a glass frit material was attached to the end plate and then a conductive coating was applied to complete the collector electrodes, and the target electrode. The phosphor was then applied as before.
  • a cathode ray storage tube comprising:
  • a target including a conductive target electrode
  • connection means for providing said target electrode with a predetermined voltage level
  • a dielectric layer for storing a charge pattern, said layer being located on one side of said target electrode,
  • a multiplicity of spaced conductive collector electrodes extending from said target electrode through the dielectric layer at least to the opposite side thereof to provide an equipotential surface on the said opposite side of said dielectric layer at substantially the same voltage level as said target electrode, said dielectric layer being substantially continuous except where interrupted by said collector electrodes,
  • said dielectric layer is formed of dielectric phosphor material.
  • the device according to claim 1 further including an insulating substrate body supporting the said target electrode wherein said target electrode is located on the side of said substrate body oriented towards said means for emitting electrons.
  • said substrate body is provided with a layer of conductive material on the side thereof towards said means for emitting electrons to provide said target electrode.
  • a cathode ray storage tube having an electron generating means adapted to direct electrons at a target in said tube and means for directing low velocity electrons at said target for driving selected areas of such target towards one of two stable potentials, the improvement comprising:
  • a target positioned in the path of electrons from said electron generating means and in the path of said low velocity electrons, said target including a target electrode,
  • said target including an insulating substrate body supporting said target electrode as a conductive layer thereon wherein said target electrode is located on the side of said substrate body oriented toward said electron generating means,
  • said substrate body being formed to provide a multi plicity of protrusions extending through said dielectric layer, said conductive layer on said insulating body forming a multiplicity of spaced conductive collector electrodes where the insulating body protrudes through said dielectric layer, said collector electrodes establishing an equipotential surface on the side of said dielectric layer toward said electron generating means at substantially the same voltage level as said target electrode,
  • said dielectric layer being substantially continuous except where interrupted by said collector electrodes.
  • each of said multiplicity of collector electrodes is substantially round in cross section and extends through said dielectric layer to provide a round conductive protrusion therethrough of small area as compared with the area of material between said collector electrodes,
  • said multiplicity of collector electrodes being arranged in regular pattern of substantially uniform density over said target electrode.
  • collector electrodes are joined by an electrically conductive means extending between said collector electrodes on the side of said target toward which electrons are emitted.
  • said tube further includes collimating electrodes disposed around the path of electrons from said beam generating means and source to such target.
  • a cathode ray storage tube comprising:
  • a multiplicity of collector electrodes extending through said dielectric layer to one side thereof in spaced and separated array where they extend through the dielectric layer, said multiplicity of electrodes being electrically interconnected to provide conductive collector surfaces proximate said one side of said dielectric layer establishing an equipotential surface on said one side,
  • said dielectric layer being substantially continuous and joined except where interrupted by said spaced collector electrodes,
  • a cathode ray storage tube having an electron beam generating means adapted to direct an electron beam at a target in said tube, and a source for directing low velocity electrons at said target for driving selected areas of such target toward one of two stable potentials, the improvement comprising:
  • said protrusions being provided with a multiplicity of collector electrodes where they extend through said dielectric layer with said electrodes being spaced and separated while being electrically interconnected to provide an equipotential surface on the side of said dielectric layer toward electron beam generating means, said protrusions providing bodies for said collector electrodes.
  • collector electrodes are interconnected by an electrically conductive means extending between said collector electrodes on the electron beam side of said target.

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Description

Sept. 29, 1970 R. A. FRANKLAND 3,531,675
CATHODE RAY STORAGE TUBE HAVING A TARGET DIELECTRIC WITH COLLECTOR ELECTRODES EXTENDING THERETHROUGH Filed Feb. 28, .1967 2 SheetsS'neet 1 39 as .38 i i MW '5;
46 +3OOV52 DEFLECTION 27 CIRCUITS 56 7+I5OV.
FIG. 2 68 .(PRIOR ART) ROGER A. FRANKLAND lNVE/VTOR B) BUCKHORN, BLORE, KLAROU/ST 8 SPAR/(MAN ATTORNEYS p Y R. A. FRANKLAND CATHQDE RAY STORAGE TUBE HAVING A TARGET DIELECTRIC WITH COLLECTQR ELECTRODES EXTENDING THERETHROUGH Filed Feb. 28, '1967' v 2 Sheets-Sheet 2 FIG. 3
so 200v. J I
A ,1 74 827A YQ f I as as ROGER A. FRANKLAND INVENTOR B) BUCKHORN, BLORE, KLAROU/ST 8 SPAR/(MAN ,arromvsrs United States Patent US. Cl. 313-68 18 Claims ABSTRACT OF THE DISCLOSURE A cathode ray storage tube provided with a storage target having a multiplicity of collector electrodes extending through the storage targets dielectric layer. These collector electrodes act to collect secondary electrons and control the electric field configuration near the surface of the storage target for the prevention of trace shadowing.
BACKGROUND OF THE INVENTION The present invention relates to cathode ray storage tubes, and particularly to cathode ray storage tubes providing improved storage accuracy.
A type of cathode ray storage tube includes electron beam generating means and one or more flood electron sources directed toward a storage target structure. The electron beam writes and sometimes detects information on the target surface and the flood electrons are employed for retaining selected areas of the target at one of two stable potentials. In areas where the electron beam has not written, such areas are retained at the negative potential of the flood electrons. However, areas of the target struck by the electron beam become positive due to secondary emission from the target. The flood electrons act to maintain these areas in a positive state inasmuch as the flood electrons are attracted to these areas and given higher velocity causing continued emission of secondary electrons. In such a tube, collector electrode means are generally employed for collecting secondary electrons, such electrode means being suitably maintained at approximately the same potential as a storage target electrode included at the back of the storage target. In one successful storage tube, the target electrode itself acts as a collector electrode, and the dielectric or phosphor layer on the surface of the target electrode is sufliciently thin and porous so that secondary electrons may pass therethrough to the target electrode. In other devices, other collector electrodes in the form of rings or Screens are employed for the collection of secondary electrons.
Unfortunately, one difliculty encountered in a number of cathode ray storage tubes is the presence of trace shadowing. Trace shadowing takes place as a display of information written by the electron beam is only partially illuminated by flood electrons. This shadowing, seen as an indistinct edge on the stored trace, is the result of aberrations in the electric field close to the target at locations where information has been written by the electron beam. A field of this type is illustrated in FIG. 2. Flood electrons entering this field are given a transverse velocity and tend to land non-uniformly on the target with resultant trace shadowing.
SUMMARY OF THE INVENTION Patented Sept. 29, 1970 c CC p-hor layer and act to provide a potential surface near the forward side of the storage target at substantially the same potential as the target electrode. As a result, the field close to the target on the electron source side thereof is substantially less distorted where written upon and trace shadowing is substantially eliminated. Flood electrons are no longer given such transverse velocity as causes the undesired distortion.
According to method aspects of the present invention, a target is advantageously formed by a photo-etching process wherein an insulating substrate body of the target is coated with metal after which a layer of photoresist is applied. The target surface is then exposed to a dot pattern mask, and the photoresist and metal between the dots is removed. The surface is etched resulting in conical shaped protrusions from above a surface of the substrate body. A thin transparent conductive layer is applied to this body and then a dielectric layer of phosphor material is applied which is substantially semicontinuous, except for the locations of the collector electrodes. The result is a regular pattern of collector electrodes whose apices extend above the surface of the phosphor layer and which are actually a protruding extension of the thin target electrode at the rear of the phosphor material.
It is accordingly an object of the present invention to provide a cathode ray storage tube having improved storage capabilities because of the substantial elimination of trace shadowing.
It is another object of the present invention to provide a cathode ray storage tube wherein the appearance of a visible display is improved, such tube having enhanced stored resolution capability as well as improved stored display readout accuracy.
It is another object of the present invention to provide a cathode ray storage tube wherein the collimation of flood gun electrons is improved.
It is a further object of the present invention to provide a cathode ray storage tube with improved means for collecting secondary electrons.
It is a further object of the present invention to provide an improved storage target having integral collector electrode means adapted for providing a more even field over written and unwritten portions of such storage target.
The subject matter which I regard as my invention is particularly pointed out and distinctly claimed in the concluding portion of this specification. The invention, however, both as to organization and method of operation, together with further advantages and objects thereof, may best be understood by reference to the following description taken in connection with the accompanying drawings wherein like reference characters refer to like elements:
DRAWINGS FIG. 1 is a schematic representation of a cathode ray storage tube according to the present invention;
FIG. 2 is a cross sectional view of one prior type of storage target;
FIG. 3 is a cross sectional view of a storage target according to the present invention;
FIG. 4 is a partial forward view of a storage target according to the present invention; and
FIG. 5 is a perspective view, partially broken away and partially in cross section of a storage target according to the present invention.
DETAILED DESCRIPTION Referring to FIG. 1 a cathode ray storage tube inculdes a storage tube envelope 10 formed of insulating material housing a principal electron gun including a filament 12, a cathode 14 for connection to a high negative voltage source, a control grid 16 and a focusing and accelerating structure .18. The electron beam produced by the principal electron gun is deflected horizontally by means of horizontal deflection plate-s 24. The deflection plates are connected to conventional deflection circuits 27 for causing selective positioning of electron beam 20. The beam is in general directed towards a target 46 at the opposite end of the tube. The storage tube is additionally provided with one or more flood type electron guns 26 each having a cathode 28, a control grid 30 and an anode 32, and which are supported inside the envelope 10 adjacent the end of the vertical deflection plates 24 closest the target. Cathodes 28 are conveniently maintained at a low voltage level, e.g. ground level, while grids 30 are suitably connected to a minus volts. Lo'w velocity electrons emitted from the flood guns diverge into a wide beam which is desirably uniformly distributed towards target 46.
A plurality of electrodes are also located on the inner surface of envelope 10. These electrodes may be provided as spaced wall coatings of conductive material, such as silver, tin oxide, aluminum, or graphite, on the interior surface of the envelope. The first electrode wall coating 34 functions primarily as a focusing electrode for the flood electrons emitted from the flood guns. It is connected to a suitable source of electrical potential, e.g. a positive 250 volts. A second electrode wall coating 36 is spaced from such first electrode and electrically connected to a positive voltage, e.g. 150 volts and functions as a focusing and collimating electrode. A third electrode wall coating 38 spaced from coating 36 is electrically connected to a positive voltage, e.g. 125 volts and also functions as a focusing and collimating electrode. Due to the collimating action of the electrode wall coating, the electrons from the flood guns are desirably substantially uniformly distributed over the surface of storage target 46 and ap proach such target at approximately right angles thereto. A fourth electrode wall coating 39 is positioned between and spaced from the wall coating 38 and the storage target 46, and is connected to a positive voltage, e.g. a positive 75 volts. In addition to focusing and collimating the flood electrons the wall coating 38 may function to some extent as a collector electrode to collect part of the secondary electrons emitted from the storage target 46.
It should be noted that a conventional resistive coating 40, e.g. Aquadag or similarly conductive material, is suitably provided on the interior of a portion of the envelopes neck portion and is electrically connected to an isolation shield (not shown) in the writing gun in such neck portion so that it serves as an extension of a second anode (also not shown) in such writing gun. The voltages applied to electrode wall coatings 34, 36, 38, and 39 are by way of example and are suitably adjusted to provide optimum collimation of the flood electrons.
Storage target 46 is provided upon insulative end plate 48 and comprises a transparent storage target electrode 50 over which is disposed a dielectric 52. The dielectric 52 is suitably P-l type phosphor and is at least semi-continuous. Target electrode 50 is a thin deposited transparent coating such as tin oxide or the like and is suitably connected to the midpoint of a voltage divider comprising resistors 56 and 58 disposed between a plus 300 volts and ground. Resistor 56 is variable and is suitably adjusted so that a voltage of approximately plus 150 volts is applied to target electrode 50. In addition, target electrode 50 may be connected to amplifying means for providing an electrical readout of information stored on the storage target.
Information may be written on this storage target via electron beam 20'. This information may be in the form of a waveform applied to the vertical deflection plates 24 while the beam is scanned horizontally with the deflection circuits 27, or intensity information may be applied to grid 16 while the beam is scanned both vertically and horizontally by deflection circuits 27. In addition to electrical readout, the information written on the storage target is visibly displayed through end plate 48 wherein such end plate is formed of transparent material, e.g. glass.
During operation, the tube potentials are adjusted such that beam 20 has a relatively high velocity for writing and is capable of producing secondary electrons when it strikes storage dielectric 52. Secondary electrons are then collected in a manner hereinafter more fully described. An elemental area of the target can be driven positive or written as a result of the secondary emission produced by electron beam '20.
A written area is retained at a relatively positive potential after beam 20 has passed such elemental area because of the action of flood electrons from flood guns 26. Flood guns 26 produce relatively low velocity electrons which strike the target but which ordinarily have insufficient velocity for writing information. When the electrons from flood guns 26 strike areas of the target upon which a positive charge has not been written, these flood electrons tend to maintain such areas at a relatively low potential near the potential of the flood gun cathode. This is the stable negative potential level of the target. However, the flood gun electrons are attracted by a positive elemental area and attain a high velocity with respect to these areas for producing continued secondary emission therefrom. Therefore these areas are maintained relatively positive or near the potential of target electrode 50. This comprises the stable positive potential level of the target. The target thus has bistable properties and is capable of retaining information written thereon inasmuch as the flood beam of electrons drives target areas to one of the two stable potentials depending upon the information previously written thereon with beam 20.
Referring to FIG. 2 a prior type of storage target is illustrated in cross-section including a substrate body in the form of a glass end plate 60. The substrate body is provided with a target electrode 62 comprising a very thin transparent conductive coating such as tin oxide or the like. Over the target electrode is disposed a dielectric 64, which is suitable as an integral layer of P1 type phosphor that may be sufliciently porous to enable secondary electrons to be transmitted therethrough and collected by the target electrode. A target of this type has previously been employed in a cathode ray storage tube of the type illustrated in 'FIG. 1.
Region 66 on the target electrode has been written by electron beam 20 so that its voltage level has been changed from a low voltage produced by flood electrons to a higher voltage near the volt level of target electrode 62, through the process of secondary emission. The electric field in front of a portion of the target in the direction of the electron sources is illustrated by equipotential electric field lines comprising the cross-section of equipotential field surfaces in front of a portion of the target. This field pattern is produced between the target and the electrode wall coatings 34, 36, 38 and 39. In regions other than region 66, the field voltage next to the surface of the target is at a low voltage level, e.g. 50 volts. However, in region 66-, the front surface of the target is at a higher voltage, e.g. 150 volts, being the voltage level of the target electrode, 62, for example when such target electrode acts as a collector through a porous phosphor dielectric layer 64. The resulting distortion in the electric field pattern in this region is illustrated out to the 200 volt level. Paths of flood electrons from the flood guns are illustrated at 68 on the drawing. The paths of these flood electrons encounter the distorted electric fields and are given a transverse velocity so that the paths become curved or spread whereby such electrons land non-uniformly on the target causing trace shadowing. These flood electrons are thus not properly collimated and the region 66 left by the writing gun is not correctly or completely illuminated by the flood electrons. The resultant aberration in the near field of the target electrode thus tends to result in an indistinct edge or multiple edge of the written information.
Referring to FIG. 3 there is illustrated a cross section of an improved storage target in accordance with the present invention. This target is employed with the cathode ray storage tube of the type illustrated in FIG. 1. The target includes a substrate body which is suitably transparent and formed of insulative material, e.g. taking the form of glass end plate 70. The substrate body is further provided with a target electrode 72 suitably comprising a very thin transparent deposited conductive coating such as tin oxide or the like supported on the glass end plate 70. Upon the target electrode 72 there is supported a substantially integral, or at least semi-continuous dielectric layer 74 suitably comprising a layer of phosphor, e.g. of the P-l type. This layer may be somewhat porous, like phosphor layer 64 but need not be.
According to the present invention, a multiplicity of collector electrodes 76 extend from the target electrode 72 and through the substantially semi-continuous dielectric layer 74 to the side of the target nearest the electron sources. These conductive electrodes desirably protrude from the otherwise substantially planar surface of dielectric layer 74 and act as collectors for the secondary electrons generated when electron beam 20 strikes the storage target. The collector electrodes extend forward about two mils from the target electrode 72, in the illustrated embodiment, and extend above the otherwise substantially planar and continuous dilectric layer 74. However, the collector electrodes 76 may protrude farther if so desired. The collector electrodes in the illustrated emmodiment are approximately conical in shape with the base of each electrode being substantially coincident with the plane of target electrode 72, and with the apex of the cone extending forwardly above the level of dielectric layer 74. However, it is to be understood the electrodes may take other shapes. Thus, these electrodes may be pyramidal in shape and may come to a point where they extend above the dielectric layer 74, or such point may be somewhat flattened. If desired the electrodes may alternatively by cylindrical. The collector electrodes 76 are electrically connected at their base to target electrode 72.
The collector electrodes 76 in the illustrated embodiment are distributed over the storage target in a regular pattern with a regular spacing between electrodes as illustrated in FIG. 4. In the illustrated embodiment, the centerto-center distance between adjacent electrodes was ap proximately six mils, this being less than the approximate diameter of the electron beam 20 employed in writing on the storage target. The diameter of such electron beam (or thetrace produced thereby) is about mils across from points halfway up the Gaussian distribution. The distance between collector electrodes is also related to the resolution properties of the target and the cathode ray storage tube employing the same. Thus, the collector electrodes six mils apart result in an approximately six mil resolution capability. For reasonable resolution it is preferred the spacing of the collector electrodes be under mils. The density of collector electrodes positioned 6 mils apart on a 5" cathode ray tube results in about 300,000 of such electrodes on the storage target. The electrodes may be placed closer together if desired. In the illustrated embodiment, the exposed raised collector area, that is the area rising above the phosphor, comprises approximately 10 percent of the storage target surface, viewed from electron source side of the target, as thus illustrated in FIG. 4. The target construction partly broken away and including a completed phosphor layer only on the left side, is illustrated in FIG. 5.
In operation, the target electrode illustrated in FIGS. 3, 4 and 5 has the advantage of providing a much more uniform or undistorted near field at and near the surface of the target electrode oriented towards the electron sources. Illustrative equipotential lines comprising cross sections of equipotential surfaces of this field are shown in FIG. 3. The field line 78 is close to the target and is at a voltage level of substantially 150 volts, this being the voltage of target electrode 72 and of the collector electrodes 76. The 200 volt field line is nearly flat. Region 82 illustrates the location where information has been written on the target by means of electron beam 20. In this region, the dielectric layer 74 has been raised to a potential of approximately volts, or the potential of target electrode 72, due to secondary emission from this region. Therefore, equipotential line 78 is closer to the dielectric layer 74 in this region. However, since there is always a relatively close-in 150 volt field line due to the action of electrodes 76, the overall eifect of writing upon the electric field is comparatively slight. The region of change of field line 78 is confined to the region between substantially adjacent electrodes 76, and close in to the target. Therefore, the more remote equipotential line 80 is substantially unaffected and remains substantially flat and undistorted as compared with the distorted field as in the case of the FIG. 2 device. Therefore, flood electrons 84 from the flood guns 26 are not substantially deflected transversely but rather proceed in a more collimated manner to the storage target. When the flood electrons almost reach the target, some distortion in the field is not capable of a serious effect on collimation. It has been found that trace shadowing is substantially eliminated in the storage target illustrated in FIG. 3, resulting in a sharper image. The substantial removal of trace shadowing improves the general appearance of the display, improves stored resolution capability, and improves stored display readout accuracy. The electric field configuration is illustrated to aid an understanding of the invention and it is understood the invention is not limited thereby.
0f course, the collector electrodes also provide ad-' vantageous means for collecting the secondary electrons produced at the storage target. Therefore, dielectric layer A 74, e.g. of phosphor or the like, need not be porous and may be thicker or multi-layer without the requirement that secondary electrons be able to pass therethrough.
The collector electrodes 76 are suitably formed as forwardly protruding raised extensions of target electrode 72. Moreover, the substrate body 70 is suitably raised at the locations of collector electrode 76 to provide an inner body of these collector electrodes with the extension of target electrode 72 providing a conducting exterior electrically connected to the remainder of target electrode 72. An exemplary method of manufacturing the storage target is described as follows. First, the glass end plate such as 70 in FIG. 3 is annealed and coated with a thin layer of nickel followed by a thin layer of gold, the nickel being used to adhere the gold to the glass end plate. The metals are suitably evaporated onto the end plate. Then a layer of photoresist material is applied over the layer of gold and the plate is baked. The surface is then exposed photographically to provide a dot pattern on the metal layer having the same general configuration as the collector electrodes as illustrated in FIG. 4, but with dots somewhat larger in diameter to correspond to the base diameter of electrodes 76, e.g. about 5 mils. The areas around the electrodes are illuminated and exposed, for example, using a light source and a contact negative comprising a pattern of opaque dots. The photoresist is developed with the areas around the dots being dissolved. The plate is then baked. The NiAu layer is etched away around the dots using gold and nickel etchants in succession with an intermediate rinse. An etchant is then applied which acts to remove the glass around the dots, the latter being protected with metal. A suitable etchant includes one part HF and one part dimethyl sulfoxide. The surface of the glass end plate 70 is lowered around these dots by etching. The etchant also has the effect of etching the glass away from underneath the exposed dots to provide conical raised protrusions 86 as illustrated in FIG. 3. The glass is removed under the metal dots at the same rate as the glass is etched downwardly. A cone results, the sides of which have an approximately 45 degree slope. Then, the glass is cleaned and a thin transparent conductive coating such as tin oxide or the like is deposited thereon to form target electrode 72 as well as completing the multiplicity of collector electrodes 76. The target now appears as illustrated on the right side of FIG. 5. The thickness of target electrode layer 72 is exaggerated for ease of illustration. Then dielectric phosphor material, e.g. a P-l type phosphor is cast into the etched end plate, e.g. using an Elvax binder and toluene solvent, between the collector electrodes in the form of substantially semi-continuous phosphor layer interrupted only by the collector electrodes 76. The plate is baked to complete the target. The completed target is illustrated on the left side of FIG. 3.
The forward portion of the target electrode may be eX- tended or shaped as desired to control the near field potential. The target electrodes may be extended forwardly to a greater height, or the forward protruding ends of the collector electrodes may be connected with very narrow strips of aluminum or gold or the like evaporated to connect between the ends of the protruding collector electrodes. The selected material should be easy to evaporate and have a sufiicient integrity to maintain its shape. In any case, it is desired that the exposed dielectric phosphor comprise the majority of the target surface and that the collector electrodes be spaced approximately as close as the desired resolution of the target.
The raised collectors inner body may be transparent or opaque, insulative or electrically continuous. A random array rather than a regular array of collector electrodes may be fabricated. For example, in one instance a glass frit material was attached to the end plate and then a conductive coating was applied to complete the collector electrodes, and the target electrode. The phosphor was then applied as before.
While I have shown and described preferred embodiments of my invention, it will be apparent to those skilled in the art that many changes and modifications may be made without departing from my invention in its broader aspects. I therefore intend the appended claims to cover all such changes and modifications as fall within the true spirit and scope of my invention.
I claim:
1. A cathode ray storage tube comprising:
a target including a conductive target electrode,
connection means for providing said target electrode with a predetermined voltage level,
a dielectric layer for storing a charge pattern, said layer being located on one side of said target electrode,
a multiplicity of spaced conductive collector electrodes extending from said target electrode through the dielectric layer at least to the opposite side thereof to provide an equipotential surface on the said opposite side of said dielectric layer at substantially the same voltage level as said target electrode, said dielectric layer being substantially continuous except where interrupted by said collector electrodes,
and means for emitting electrons toward the side of said target opposite said target electrode for establishing said charge pattern on said dielectric layer and for directing low velocity electrons at the side of said target opposite said target electrode for driv ing selected areas of said dielectric layer toward one of two stable potentials to retain a charge pattern on said target.
2. The device according to claim 1 wherein said dielectric layer is formed of dielectric phosphor material.
3. The device according to claim 1 further including an insulating substrate body supporting the said target electrode wherein said target electrode is located on the side of said substrate body oriented towards said means for emitting electrons.
4. The device according to claim 1 wherein the multiplicity of electrodes extending through the dielectric layer protrude above the surface of said dielectric layer towards said means for emitting electrons.
5. The device according to claim 1 wherein the dis tance between centers of such collector electrodes where they extend through the dielectric layer is effectively less than the diameter of the electron beam from said electron beam generating means.
6. The device according to claim 1 wherein the dis tance between centers of said collector electrodes is less than 15 mils.
7. The device according to claim 1 wherein the centers of said collector electrodes are spaced approximately as close as the desired resolution of said cathode ray storage tube.
8. The device according to claim 3 wherein said substrate body is provided with a layer of conductive material on the side thereof towards said means for emitting electrons to provide said target electrode.
9. The device according to claim 8 wherein said substate body and said conductive material providing said target electrode are both transparent.
10. In a cathode ray storage tube having an electron generating means adapted to direct electrons at a target in said tube and means for directing low velocity electrons at said target for driving selected areas of such target towards one of two stable potentials, the improvement comprising:
a target positioned in the path of electrons from said electron generating means and in the path of said low velocity electrons, said target including a target electrode,
said target including an insulating substrate body supporting said target electrode as a conductive layer thereon wherein said target electrode is located on the side of said substrate body oriented toward said electron generating means,
and a dielectric layer located on the side of said target electrode oriented toward said electron generating means and said low velocity electrons,
said substrate body being formed to provide a multi plicity of protrusions extending through said dielectric layer, said conductive layer on said insulating body forming a multiplicity of spaced conductive collector electrodes where the insulating body protrudes through said dielectric layer, said collector electrodes establishing an equipotential surface on the side of said dielectric layer toward said electron generating means at substantially the same voltage level as said target electrode,
said dielectric layer being substantially continuous except where interrupted by said collector electrodes.
11. The device according to claim 10 wherein the protrusions from said substrate body of electrically insulating material providing bases for said collector electrodes are substantially conical in shape.
12. The device according to claim 1 wherein each of said multiplicity of collector electrodes is substantially round in cross section and extends through said dielectric layer to provide a round conductive protrusion therethrough of small area as compared with the area of material between said collector electrodes,
said multiplicity of collector electrodes being arranged in regular pattern of substantially uniform density over said target electrode.
13. The device according to claim 1 wherein said collector electrodes are joined by an electrically conductive means extending between said collector electrodes on the side of said target toward which electrons are emitted.
14. The device according to claim 1 wherein said tube further includes collimating electrodes disposed around the path of electrons from said beam generating means and source to such target.
15. A cathode ray storage tube comprising:
a target including a dielectric layer separate from the tubes faceplate,
a multiplicity of collector electrodes extending through said dielectric layer to one side thereof in spaced and separated array where they extend through the dielectric layer, said multiplicity of electrodes being electrically interconnected to provide conductive collector surfaces proximate said one side of said dielectric layer establishing an equipotential surface on said one side,
said dielectric layer being substantially continuous and joined except where interrupted by said spaced collector electrodes,
means for directing an electron beam toward said one side of said target for establishing a charge pattern on said dielectric layer,
and means for directing low velocity electrons at said one side of said target for driving selected areas of such target toward one of two stable potentials.
16. In a cathode ray storage tube having an electron beam generating means adapted to direct an electron beam at a target in said tube, and a source for directing low velocity electrons at said target for driving selected areas of such target toward one of two stable potentials, the improvement comprising:
said protrusions being provided with a multiplicity of collector electrodes where they extend through said dielectric layer with said electrodes being spaced and separated while being electrically interconnected to provide an equipotential surface on the side of said dielectric layer toward electron beam generating means, said protrusions providing bodies for said collector electrodes.
17. The device according to claim 15 wherein said 10 dielectric layer is formed of dielectric phosphor material.
18. The device according to claim 15 wherein said collector electrodes are interconnected by an electrically conductive means extending between said collector electrodes on the electron beam side of said target.
References Cited UNITED STATES PATENTS 2,015,570 9/1935 Sabbah et al. 3l3--73 X 2,289,205 7/1942 Nagy et al. 31373 X 2,392,161 l/1946 Leverenz 3l3351 X 3,157,811 11/1964 Stone 313-73 3,293,474 12/1966 Gibson 313-92 X 3,321,657 5/1967 Granitsas et al. 313-73 3,366,817 1/1968 Miller 313-73 JAMES W. LAWRENCE, Primary Examiner V. LAFRANCHI, Assistant Examiner US. Cl. X.R.
UNITED STATES PATENT OFFICE CERTIFICATE O F CORRECTION Dated pt. 29, 1970 Roger A. Frankland Patent No.
Inventor(s) Column 1, line Column 3, line Column 4, line Column 5, line line Column 8, line (SEAL) Amt:
EdmflLLFletchmIr.
Atteafing Officer It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:
after "given" insert --a-- "coating" should be --coatings-. "suitable as" should be --suitably--. "dilectric" should be --dielectric, "modiment" should be --bodiment--. "state" should be --strate-.
SIGNED AND SEALED FEB mm mm 3. 50mm, JR. fomlssioner of Patents FORM PC3-1050 (10-69]
US619904A 1967-02-28 1967-02-28 Cathode ray storage tube having a target dielectric with collector electrodes extending therethrough Expired - Lifetime US3531675A (en)

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US3710179A (en) * 1971-09-14 1973-01-09 Tektronix Inc Storage tube having transmission target with low differential cutoff
US3710173A (en) * 1970-06-17 1973-01-09 Tektronix Inc Direct viewing storage tube having mesh halftone target and nonmesh bistable target
US3720856A (en) * 1970-07-29 1973-03-13 Westinghouse Electric Corp Binary material field emitter structure
DE2338902A1 (en) * 1972-08-03 1974-02-14 Tektronix Inc STORAGE TARGET ELECTRODE
DE2420001A1 (en) * 1973-04-30 1974-11-07 Tektronix Inc STORAGE TARGET FOR A CATHODE BEAM TUBE AND THE PROCESS FOR MANUFACTURING IT
US3978366A (en) * 1975-07-28 1976-08-31 Tektronix, Inc. Cathode ray storage tube having a target dielectric provided with collector electrode segments extending therethrough
US4039896A (en) * 1976-01-02 1977-08-02 Tektronix, Inc. Cathode ray storage tube having a target dielectric provided with particulate segments of collector electrode extending therethrough
DE2703813A1 (en) * 1976-02-18 1977-08-25 Tektronix Inc CATHODE TUBE STORAGE SCREEN WITH EXTENDED LIFE
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US4106937A (en) * 1976-01-02 1978-08-15 Tektronix, Inc. Cathode ray storage tube having a target dielectric provided with particulate segments of collector electrode extending therethrough
DE2824102A1 (en) * 1977-06-02 1978-12-07 Tektronix Inc DIRECT VIEWING CATHODE BEAM STORAGE TUBE AND PROCESS FOR DISPLAYING STORED AND WITCHED STORAGE IMAGES ON A STORAGE DIELECTRIC OF SUCH TUBES
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US3710173A (en) * 1970-06-17 1973-01-09 Tektronix Inc Direct viewing storage tube having mesh halftone target and nonmesh bistable target
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DE2338902A1 (en) * 1972-08-03 1974-02-14 Tektronix Inc STORAGE TARGET ELECTRODE
DE2420001A1 (en) * 1973-04-30 1974-11-07 Tektronix Inc STORAGE TARGET FOR A CATHODE BEAM TUBE AND THE PROCESS FOR MANUFACTURING IT
US3956662A (en) * 1973-04-30 1976-05-11 Tektronix, Inc. Cathode ray storage tube having a target dielectric provided with particulate segments of collector electrode extending therethrough
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DE2703813A1 (en) * 1976-02-18 1977-08-25 Tektronix Inc CATHODE TUBE STORAGE SCREEN WITH EXTENDED LIFE
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DE2824102A1 (en) * 1977-06-02 1978-12-07 Tektronix Inc DIRECT VIEWING CATHODE BEAM STORAGE TUBE AND PROCESS FOR DISPLAYING STORED AND WITCHED STORAGE IMAGES ON A STORAGE DIELECTRIC OF SUCH TUBES
US20160233062A1 (en) * 2015-02-10 2016-08-11 Hamilton Sunstrand Corporation System and Method for Enhanced Ion Pump Lifespan
US10262845B2 (en) 2015-02-10 2019-04-16 Hamilton Sundstrand Corporation System and method for enhanced ion pump lifespan
US10665437B2 (en) * 2015-02-10 2020-05-26 Hamilton Sundstrand Corporation System and method for enhanced ion pump lifespan
US11081327B2 (en) 2015-02-10 2021-08-03 Hamilton Sundstrand Corporation System and method for enhanced ion pump lifespan
US11742191B2 (en) 2015-02-10 2023-08-29 Hamilton Sundstrand Corporation System and method for enhanced ion pump lifespan

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