US3885180A - Microchannel imaging display device - Google Patents

Microchannel imaging display device Download PDF

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US3885180A
US3885180A US377987A US37798773A US3885180A US 3885180 A US3885180 A US 3885180A US 377987 A US377987 A US 377987A US 37798773 A US37798773 A US 37798773A US 3885180 A US3885180 A US 3885180A
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microchannel plate
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electrodes
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Jr Stanley L Carts
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US Department of Army
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J43/00Secondary-emission tubes; Electron-multiplier tubes
    • H01J43/04Electron multipliers
    • H01J43/06Electrode arrangements
    • H01J43/18Electrode arrangements using essentially more than one dynode
    • H01J43/24Dynodes having potential gradient along their surfaces
    • H01J43/246Microchannel plates [MCP]
    • 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
    • H01J29/46Arrangements of electrodes and associated parts for generating or controlling the ray or beam, e.g. electron-optical arrangement
    • H01J29/467Control electrodes for flat display tubes, e.g. of the type covered by group H01J31/123
    • 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
    • H01J31/10Image or pattern display tubes, i.e. having electrical input and optical output; Flying-spot tubes for scanning purposes
    • H01J31/12Image or pattern display tubes, i.e. having electrical input and optical output; Flying-spot tubes for scanning purposes with luminescent screen
    • H01J31/128Image or pattern display tubes, i.e. having electrical input and optical output; Flying-spot tubes for scanning purposes with luminescent screen provided with control means permitting the electron beam to reach selected parts of the screen, e.g. digitally controlled display tubes

Definitions

  • An input sequential switcher and an output sequential switcher have voltage differentials that are separately swept across each set of lines such that when the voltage differentials are applied on directly opposite sides of the microchannel plate, while the regular bias voltage is applied across the MCP, there is high electron gain.
  • a photoemissive panel emitting a uniform flow of electrons therefrom, is positioned adjacent the input set of metallic lines, and a luminescent screen, such as phosphor, is positioned adjacent the output set of metallic lines for displaying an image according to electron flow caused by the differential sequential switching voltages.
  • the technology of this invention involves providing an image display by use of a microchannel plate in which each of the input and output electrodes on the microchannel plate comprise a set of long, thin, parallel, metallic lines with the sets of metallic lines perpendicular to each other.
  • Differential voltages are sequentially switched across the input electrode metallic lines and across the output electrode metallic lines.
  • the difference in magnitude of the differential voltages at a crossover point of the two perpendicular electrodes causes an increase in electron multiplication at this par ticular point.
  • application of the regular bias voltage in series with the sequential voltages across the MCP causes an intense output at the crossover point of the sequential voltages since the total voltage is much greater only at that point.
  • a photoemissive panel close to the input electrode furnishes a uniform flow of electrons into the channels at the input side of the microchannel plate. This uniform flow of electrons is changed into a specific pattern at the output of the microchannel plate according to the switching of the regular bias voltage and the sequentially switched differential voltages that are applied to the input and output electrodes,
  • the electrons from the output of the microchannel plate strike a electroluminescent screen, such as a phosphor screen.
  • a electroluminescent screen such as a phosphor screen.
  • the phosphor screen is proximity focused with the output electrode of the microchannel plate to form an object image pattern that is the same as the electron multiplication pattern from the microchannel plate.
  • the input and output electrode metallic lines may be formed on the input and output sides of the microchannel plate by various methods, such as evaporation through a mask for laying the parallel lines or evaporating a continuous electrode and then photoetching the parallel lines therein in a manner similar to that used to produce printed circuits.
  • FIG. 1 illustrates a side view of the imaging display device of the present invention
  • FIG. 2 shows a partial side view of the microchannel plate and the electrode attached thereto
  • FIG. 3 illustrates a sectional view of the microchannel plate.
  • FIG. 1 illustrates a diagrammatic side view of the microchannel imaging display device in which all elements are enclosed in a vacuum environment, except sequential switches 16 and 18.
  • An electron emitting panel 10 such as a thermionic panel or a luminescentphotoemissive composite panel, is used to generate an even flow of electrons therefrom toward an input side of a microchannel plate 14.
  • the electrons may be evenly emitted from by even heating of the panel in case the panel is thermionic or by flooding the input side 9 of the panel in case of a luminescent photoemissive composite panel.
  • microchannel plate 14 having the usual one solid input electrode and one solid output electrode
  • a unique pattern of long, thin parallel input and output electrodes is provided on the microchannel plate with the input and output electrodes being perpendicular to each other.
  • This novel pattern of electrodes are formed on each side of the basic channeled microchannel plate by evaporation methods well known in the art, such as evaporation through a mask or evaporating a continuous electrode and then photoetching lines therein.
  • the separate parallel input electrodes I7 are connected to input sequential switcher I6, and common input electrode 15 is connected to all of the input electrodes I7 and back to the negative side of a regular MCP bias voltage source V through switch SW1. Electrodes I5 and 17 are evaporated on the input side of 14 simultaneously.
  • Electrodes 19 and a common output electrode connected to electrodes 19 on the output side are likewise simultaneously evaporated on the output side of the microchannel plate.
  • Output electrodes I9 are connected to output sequential switcher 18, and the common output electrode is connected to all of the electrodes 19 and back to the positive side of a regular MCP bias voltage source V
  • These electrodes may be made of any good conduction material which is easy to evaporate, such as gold, silver, aluminum, etc.
  • the material that the microchannel plate is made of may be glass, aluminum oxide, or some other semiconductor material used in producing the channeled wafer.
  • the channels are first produced in the wafer and then the electrodes are formed on each side thereof. In the method of evaporating the metallic lines on the wafer, some of the metal will go into the outer edges of the channels but not enough to appreciably hinder any electrons entering the channels on the input electrode side or exiting from the output electrode side of the wafer.
  • electron emitting panel 10, mi crochannel plate 14, and light emitting screen 20 are all enclosed in a vacuum envelope or housing (not shown).
  • the display device has the advantages of being very thin and having high resolution.
  • the display device may be as thin as inch.
  • the overall width may be increased without increasing the thickness more than A inch.
  • FIG. 2 As a reference, when a suitable voltage is applied on input metallic line 17a and output metallic line 19a simultaneously (with both lines shown heavier than the other lines in FIG, 1 for representative purposes), electrons entering channels 25, which are at the crossing point of 17a and will be accelerated and multiplied through channels 25 when voltage V is also switched on by closing switch SW]. These multiplied electrons emitted from the output side of microchannel plate I4 at the crossing point is proximity focused on electroluminescent panel 20 at a point represented by 20a, resulting in a visible output on the opposite side of screen 20, represented by 23.
  • the crossover point of the differential voltages from 16 and 18 may be determined by momentarily switch in the MCP bias voltage V in series therewith and observing a digital output from screen 20. Any crossover point between the multiple electrodes 17 and 19 may be chosen by selectively switching V across the MCP resulting in visible amplification at the chosen point at the output of the screen 20.
  • the sequential switching voltages from 16 and 18 may be relative slow or fast. For example, switching may be as fast as 100 millisecond total scan time by use of electronic switching.
  • Voltage V is about 5 to 100 d.c. volts with the input side of 14 being positive relative to the cathode 10. If the input side of 14 is at ground potential, voltage V may be a negative 5 to 100 d.c. volts and serve the same purpose.'The spacing between elements and 14 is not critical since image focusing of the uniform flow of electrons is not involved in this space. Voltage V,-,. is used to maintain a slight electric field between 10 and 14 to accelerate the uniform flow electron toward the input of 14. Using the above noted voltage values of V typical spacing between 10 and 14 is about /2 of an inch.
  • the voltage of V plus the voltage across electrodes 17 and 19 caused by switching on switches 16 and 18 should total about 300 to 1,000 volts.
  • the differential voltages may be such that the voltage on the active electrode 19 may be about 300 to 1000 do volts positive when the total voltage on the input side of 14, i.e. on electrode 15 and the active electrode 17, is at ground potential. Alter nately if the voltages on electrode 15 and active electrode 17 are above ground potential by 5 to 100 do volts then the voltage on active electrode 19 may be positive 305 to I050 d.c. volts. Now with these sequen tial differential voltages from 16 and 18 scanning the electrodes on opposite sides of 14, voltage V may be switched by switch SW1 into common electrode 15 in series with these differential voltages.
  • V is about 500 d.c, volts positive on the output common electrode (notshown) and is in series with the differential voltages from 16 and 18 of about 500 do volts. Only the channels at the crossover point where voltages on lines 17 and 19 intersect will there be high electron gain. when voltage V is switched in series therewith. The remaining channels will have gains that are less than unity. Therefore, the rate of switching V within one complete cycle of a sweep of differential voltages from 16 and 18 on electrodes 17 and 19 respectively determines the total image at the output of screen 20. Also, the variation of the total voltage determines the magnitude of electron gain and the intensity of the digital output image from screen 20. Any suitable switching device may be used to switch sequential switching voltages l6 and 18, and that of switch SW1. These switching devices may be mechanically controlled for slow switching, or electronically controlled for much faster switching. Electronic switching may use integrated circuit technology for the scanning circuits since these integrated circuits satisfy the need for small size and high switching speeds.
  • the screen voltage V is a positive voltage of about 5,000 d.c. volts and is used to establish the proper voltage V between the output of 14 and the screen for proximity focusing the electrons on screen 20.
  • the spacing between the output of 14 and 20 is about Vs of an inch. However, proper proximity focusing may he acquired by changing the spacing of 14 and 20 and voltage V simultaneously to appropriate valves.
  • a television type presentation can be provided with full contrast.
  • the resolution capability is only limited by the spacing of the thin input and output electrodes and the spacing of the channels. Even though the overall thickness may be about A of an inch the display size may be increased without increasing the thickness or sacrificing display resolution. Display size limitations appear to be limited only to the measurements that a microchannel may be fabricated.
  • An image display device comprising:
  • an electron producing means for producing a uniform flow of electrons
  • microchannel plate electron multiplier positioned adjacent said electron producing means
  • means for selectively sequentially switching electron accelerating voltages across said microchannel plate electron multiplier said means for selectively sequentially switching electron accelerating voltage further comprising:
  • An image display device as set forth in claim 1 microchannel plate for producing an image diswherein said means for converting electronic energy play according to said sequentially switched elecinto visible energy is a phosphor screen. tron accelerating voltages.

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  • Cathode-Ray Tubes And Fluorescent Screens For Display (AREA)

Abstract

A display device using a microchannel plate electron multiplier with a set of fine, closely spaced, parallel continuous metallic lines deposited on each side of the microchannel plate with each set of metallic lines being perpendicular to each other. An input sequential switcher and an output sequential switcher have voltage differentials that are separately swept across each set of lines such that when the voltage differentials are applied on directly opposite sides of the microchannel plate, while the regular bias voltage is applied across the MCP, there is high electron gain. A photoemissive panel, emitting a uniform flow of electrons therefrom, is positioned adjacent the input set of metallic lines, and a luminescent screen, such as phosphor, is positioned adjacent the output set of metallic lines for displaying an image according to electron flow caused by the differential sequential switching voltages.

Description

United States Patent Carts, Jr. May 20, 1975 MICROCHANNEL IMAGING DISPLAY Primary Examiner-R. V. Rolinec DEVICE Assistant Examiner-E. R. La Roche Attorney, Agent, or Firm-Robert P. Gibson; Nathan [75] Inventor. S/tznley L. Carts, Jr., Alexandria, Edelberg; Max L. Harwell [73] Assignee: The United States Government [57] ABSTRACT SDegetary of the Army washmgmn A display device using a microchannel plate electron multiplier with a set of line, closely spaced, parallel [22] Filed: July 10, 1973 continuous metallic lines deposited on each side of the App]. No.: 377,987
microchannel plate with each set of metallic lines being perpendicular to each other. An input sequential switcher and an output sequential switcher have voltage differentials that are separately swept across each set of lines such that when the voltage differentials are applied on directly opposite sides of the microchannel plate, while the regular bias voltage is applied across the MCP, there is high electron gain. A photoemissive panel, emitting a uniform flow of electrons therefrom, is positioned adjacent the input set of metallic lines, and a luminescent screen, such as phosphor, is positioned adjacent the output set of metallic lines for displaying an image according to electron flow caused by the differential sequential switching voltages.
2 Claims, 3 Drawing Figures l7 Vic l5 mPur SW1 SEQUENTIAL I) SWITCHER T 2 oureur Vso I90 SEQUENTIAL 11 SWITCHER I I I l l it i r: Vs ,1/, 2o
ll I 20a PATENTED HAY 2 0 IHYS INPUT SEQUENTIAL SWITCHER OUTPUT SEQUENTIAL SWITCHER FIG. 3
MICROCI-IANNEL IMAGING DISPLAY DEVICE The invention described herein may be manufactured, used, and licensed by or for the Government for governmental purposes without the payment to me of any royalty thereon.
BACKGROUND AND SUMMARY OF THE INVENTION The technology of this invention involves providing an image display by use of a microchannel plate in which each of the input and output electrodes on the microchannel plate comprise a set of long, thin, parallel, metallic lines with the sets of metallic lines perpendicular to each other. Differential voltages are sequentially switched across the input electrode metallic lines and across the output electrode metallic lines. The difference in magnitude of the differential voltages at a crossover point of the two perpendicular electrodes causes an increase in electron multiplication at this par ticular point. While the sequential voltages are being swept across the input and output electrodes, application of the regular bias voltage in series with the sequential voltages across the MCP causes an intense output at the crossover point of the sequential voltages since the total voltage is much greater only at that point.
A photoemissive panel close to the input electrode furnishes a uniform flow of electrons into the channels at the input side of the microchannel plate. This uniform flow of electrons is changed into a specific pattern at the output of the microchannel plate according to the switching of the regular bias voltage and the sequentially switched differential voltages that are applied to the input and output electrodes,
The electrons from the output of the microchannel plate strike a electroluminescent screen, such as a phosphor screen. The phosphor screen is proximity focused with the output electrode of the microchannel plate to form an object image pattern that is the same as the electron multiplication pattern from the microchannel plate.
The input and output electrode metallic lines may be formed on the input and output sides of the microchannel plate by various methods, such as evaporation through a mask for laying the parallel lines or evaporating a continuous electrode and then photoetching the parallel lines therein in a manner similar to that used to produce printed circuits.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 illustrates a side view of the imaging display device of the present invention;
FIG. 2 shows a partial side view of the microchannel plate and the electrode attached thereto; and
FIG. 3 illustrates a sectional view of the microchannel plate.
DESCRIPTION OF PREFERRED EMBODIMENT FIG. 1 illustrates a diagrammatic side view of the microchannel imaging display device in which all elements are enclosed in a vacuum environment, except sequential switches 16 and 18. An electron emitting panel 10, such as a thermionic panel or a luminescentphotoemissive composite panel, is used to generate an even flow of electrons therefrom toward an input side of a microchannel plate 14. The electrons may be evenly emitted from by even heating of the panel in case the panel is thermionic or by flooding the input side 9 of the panel in case of a luminescent photoemissive composite panel. Instead of microchannel plate 14 having the usual one solid input electrode and one solid output electrode, a unique pattern of long, thin parallel input and output electrodes is provided on the microchannel plate with the input and output electrodes being perpendicular to each other. This novel pattern of electrodes are formed on each side of the basic channeled microchannel plate by evaporation methods well known in the art, such as evaporation through a mask or evaporating a continuous electrode and then photoetching lines therein. The separate parallel input electrodes I7 are connected to input sequential switcher I6, and common input electrode 15 is connected to all of the input electrodes I7 and back to the negative side of a regular MCP bias voltage source V through switch SW1. Electrodes I5 and 17 are evaporated on the input side of 14 simultaneously. Separate parallel output electrodes 19 and a common output electrode connected to electrodes 19 on the output side (with the output side not shown) are likewise simultaneously evaporated on the output side of the microchannel plate. Output electrodes I9 are connected to output sequential switcher 18, and the common output electrode is connected to all of the electrodes 19 and back to the positive side of a regular MCP bias voltage source V These electrodes may be made of any good conduction material which is easy to evaporate, such as gold, silver, aluminum, etc. The material that the microchannel plate is made of may be glass, aluminum oxide, or some other semiconductor material used in producing the channeled wafer. The channels are first produced in the wafer and then the electrodes are formed on each side thereof. In the method of evaporating the metallic lines on the wafer, some of the metal will go into the outer edges of the channels but not enough to appreciably hinder any electrons entering the channels on the input electrode side or exiting from the output electrode side of the wafer.
A light emitting screen 20, preferably coated with some good light emitting source such as phosphor, is positioned to be proximity focused in the well known manner, with the output side of the microchannel plate 14 when proper bias voltages are applied to the microchannel plate and to screen 20. In operation of the image display device, electron emitting panel 10, mi crochannel plate 14, and light emitting screen 20 are all enclosed in a vacuum envelope or housing (not shown). The display device has the advantages of being very thin and having high resolution. The display device may be as thin as inch. The overall width may be increased without increasing the thickness more than A inch.
Using FIG. 2 as a reference, when a suitable voltage is applied on input metallic line 17a and output metallic line 19a simultaneously (with both lines shown heavier than the other lines in FIG, 1 for representative purposes), electrons entering channels 25, which are at the crossing point of 17a and will be accelerated and multiplied through channels 25 when voltage V is also switched on by closing switch SW]. These multiplied electrons emitted from the output side of microchannel plate I4 at the crossing point is proximity focused on electroluminescent panel 20 at a point represented by 20a, resulting in a visible output on the opposite side of screen 20, represented by 23.
By sequentially scanning the input electrodes 17 with voltages from 16 and sequentially scanning the output electrodes 19 with voltages from 18, the crossover point of the differential voltages from 16 and 18 may be determined by momentarily switch in the MCP bias voltage V in series therewith and observing a digital output from screen 20. Any crossover point between the multiple electrodes 17 and 19 may be chosen by selectively switching V across the MCP resulting in visible amplification at the chosen point at the output of the screen 20. The sequential switching voltages from 16 and 18 may be relative slow or fast. For example, switching may be as fast as 100 millisecond total scan time by use of electronic switching.
Voltage V is about 5 to 100 d.c. volts with the input side of 14 being positive relative to the cathode 10. If the input side of 14 is at ground potential, voltage V may be a negative 5 to 100 d.c. volts and serve the same purpose.'The spacing between elements and 14 is not critical since image focusing of the uniform flow of electrons is not involved in this space. Voltage V,-,. is used to maintain a slight electric field between 10 and 14 to accelerate the uniform flow electron toward the input of 14. Using the above noted voltage values of V typical spacing between 10 and 14 is about /2 of an inch.
The voltage of V plus the voltage across electrodes 17 and 19 caused by switching on switches 16 and 18 should total about 300 to 1,000 volts. As for the individual voltages, the differential voltages may be such that the voltage on the active electrode 19 may be about 300 to 1000 do volts positive when the total voltage on the input side of 14, i.e. on electrode 15 and the active electrode 17, is at ground potential. Alter nately if the voltages on electrode 15 and active electrode 17 are above ground potential by 5 to 100 do volts then the voltage on active electrode 19 may be positive 305 to I050 d.c. volts. Now with these sequen tial differential voltages from 16 and 18 scanning the electrodes on opposite sides of 14, voltage V may be switched by switch SW1 into common electrode 15 in series with these differential voltages. Preferably the value of V is about 500 d.c, volts positive on the output common electrode (notshown) and is in series with the differential voltages from 16 and 18 of about 500 do volts. Only the channels at the crossover point where voltages on lines 17 and 19 intersect will there be high electron gain. when voltage V is switched in series therewith. The remaining channels will have gains that are less than unity. Therefore, the rate of switching V within one complete cycle of a sweep of differential voltages from 16 and 18 on electrodes 17 and 19 respectively determines the total image at the output of screen 20. Also, the variation of the total voltage determines the magnitude of electron gain and the intensity of the digital output image from screen 20. Any suitable switching device may be used to switch sequential switching voltages l6 and 18, and that of switch SW1. These switching devices may be mechanically controlled for slow switching, or electronically controlled for much faster switching. Electronic switching may use integrated circuit technology for the scanning circuits since these integrated circuits satisfy the need for small size and high switching speeds.
The screen voltage V is a positive voltage of about 5,000 d.c. volts and is used to establish the proper voltage V between the output of 14 and the screen for proximity focusing the electrons on screen 20. The spacing between the output of 14 and 20 is about Vs of an inch. However, proper proximity focusing may he acquired by changing the spacing of 14 and 20 and voltage V simultaneously to appropriate valves.
A television type presentation can be provided with full contrast. The resolution capability is only limited by the spacing of the thin input and output electrodes and the spacing of the channels. Even though the overall thickness may be about A of an inch the display size may be increased without increasing the thickness or sacrificing display resolution. Display size limitations appear to be limited only to the measurements that a microchannel may be fabricated.
It should be understood, of course, that the foregoing disclosure relates to only a preferred embodiment of the invention and that numerous modifications or alterations may be made therein without departing from the spirit and the scope of the invention as set forth in the appended claims.
I claim:
1. An image display device comprising:
an electron producing means for producing a uniform flow of electrons;
a microchannel plate electron multiplier positioned adjacent said electron producing means;
means for selectively sequentially switching electron accelerating voltages across said microchannel plate electron multiplier, said means for selectively sequentially switching electron accelerating voltage further comprising:
a set of thin parallel input electrodes on the input side of said microchannel plate that are attached to an input sequential switcher for cyclically sweeping instantaneous input sequential voltages across each of said input electrodes;
a set of thin parallel output electrodes on the output side of said microchannel plate that are perpendicular to said input electrodes and are attached to an output sequential switcher for cyclically sweeping instantaneous output sequential voltage across each of said output electrodes wherein said cyclically sweeping instantaneous input and output sequential voltages cyclically produce a sweep of cross-over voltage points over the entire face of said microchannel plate; and
a common input electrode connected to all of said set of thin parallel input electrodes,
a common output electrode connected to all of said set of thin parallel output electrodes;
a regular bias voltage connected in series with said cyclically sweeping instantaneous input and output sequential voltages through a switch across said microchannel plate wherein said regular bias voltage is connected between said common input electrode and said common output electrode to serially add said regular bias voltage to said cyclically sweeping instantaneous input and output side of said microchannel plate at said crossover point of said input and output sequential voltages and whereby said regular bias voltage is repeatedly switched on within one complete cycle of said cyclically sweeping instantaneous input and output sequential voltages to selectively provide said high electron density area in a desired pattern; and means for converting electronic en- 3,885,180 6 ergy into visible energy at said output side of said 2. An image display device as set forth in claim 1 microchannel plate for producing an image diswherein said means for converting electronic energy play according to said sequentially switched elecinto visible energy is a phosphor screen. tron accelerating voltages.

Claims (2)

1. An image display device comprising: an electron producing means for producing a uniform flow of electrons; a microchannel plate electron multiplier positioned adjacent said electron producing means; means for selectively sequentially switching electron accelerating voltages across said microchannel plate electron multiplier, said means for selectively sequentially switching electron accelerating voltage further comprising: a set of thin parallel input electrodes on the input side of said microchannel plate that are attached to an input sequential switcher for cyclically sweeping instantaneous input sequential voltages across each of said input electrodes; a set of thin parallel output electrodes on the output side of said microchannel plate that are perpendicular to said input electrodes and are attached to an output sequential switcher for cyclically sweeping instantaneous output sequential voltage across each of said output electrodes wherein said cyclically sweeping instantaneous input and output sequential voltages cyclically produce a sweep of cross-over voltage points over the entire face of said microchannel plate; and a common input electrode connected to all of said set of thin parallel input electrodes; a common output electrode connected to all of said set of thin parallel output electrodes; a regular bias voltage connected in series with said cyclically sweeping instantaneous input and output sequential voltages through a switch across said microchannel plate wherein said regular bias voltage is connected between said common input electrode and said common output electrode to serially add said regular bias voltage to said cyclically sweeping instantaneous input and output side of said microchannel plate at said crossover point of said input and output sequential voltages and whereby said regular bias voltage is repeatedly switched on within one complete cycle of said cyclically sweeping instantaneous input and output sequential voltages to selectively provide said high electron density area in a desired pattern i and, A means for converting electronic energy into visible energy at said output side of said microchannel plate for producing an image display according to said sequentially switched electron accelerating voltages.
2. An image display device as set forth in claim 1 wherein said means for converting electronic energy into visible energy is a phosphor screen.
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Cited By (13)

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US4020376A (en) * 1976-03-05 1977-04-26 The United States Of America As Represented By The Secretary Of The Army Miniature flat panel two microchannel plate picture element array image intensifier tube
US4031552A (en) * 1976-03-05 1977-06-21 The United States Of America As Represented By The Secretary Of The Army Miniature flat panel photocathode and microchannel plate picture element array image intensifier tube
US4184069A (en) * 1978-03-28 1980-01-15 The United States Of America As Represented By The Secretary Of The Army Orthogonal array faceplate wafer tube display
US4306953A (en) * 1979-11-05 1981-12-22 American Can Company Cationically polymerizable compositions containing sulfonium salt photoinitiators and stable free radicals as odor suppressants and _method of polymerization using same
US4577133A (en) * 1983-10-27 1986-03-18 Wilson Ronald E Flat panel display and method of manufacture
US5086248A (en) * 1989-08-18 1992-02-04 Galileo Electro-Optics Corporation Microchannel electron multipliers
US5838119A (en) * 1994-01-18 1998-11-17 Engle; Craig D. Electronic charge store mechanism
US6570315B1 (en) * 1998-05-22 2003-05-27 Beijing New Century De'en S&T Development Co., Ltd. Field ion display device
US20040183028A1 (en) * 2003-03-19 2004-09-23 Bruce Laprade Conductive tube for use as a reflectron lens
WO2005055268A2 (en) * 2003-11-28 2005-06-16 Imperial College Innovations Limited Gated image intensifier
US20060077755A1 (en) * 2001-02-23 2006-04-13 Japan Science And Technology Corporation Process and apparatus for producing emulsion and microcapsules
US20090294659A1 (en) * 2008-05-30 2009-12-03 Tsukasa Shishika Time-Of-Flight Mass Spectrometer
US20100090098A1 (en) * 2006-03-10 2010-04-15 Laprade Bruce N Resistive glass structures used to shape electric fields in analytical instruments

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US3634712A (en) * 1970-03-16 1972-01-11 Itt Channel-type electron multiplier for use with display device

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US3634712A (en) * 1970-03-16 1972-01-11 Itt Channel-type electron multiplier for use with display device

Cited By (20)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4031552A (en) * 1976-03-05 1977-06-21 The United States Of America As Represented By The Secretary Of The Army Miniature flat panel photocathode and microchannel plate picture element array image intensifier tube
US4020376A (en) * 1976-03-05 1977-04-26 The United States Of America As Represented By The Secretary Of The Army Miniature flat panel two microchannel plate picture element array image intensifier tube
US4184069A (en) * 1978-03-28 1980-01-15 The United States Of America As Represented By The Secretary Of The Army Orthogonal array faceplate wafer tube display
US4306953A (en) * 1979-11-05 1981-12-22 American Can Company Cationically polymerizable compositions containing sulfonium salt photoinitiators and stable free radicals as odor suppressants and _method of polymerization using same
US4577133A (en) * 1983-10-27 1986-03-18 Wilson Ronald E Flat panel display and method of manufacture
US5086248A (en) * 1989-08-18 1992-02-04 Galileo Electro-Optics Corporation Microchannel electron multipliers
US5838119A (en) * 1994-01-18 1998-11-17 Engle; Craig D. Electronic charge store mechanism
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