Claims
- 1. A field emission display baseplate comprising:
a substrate; a linear array of emitters formed on the substrate; a dielectric layer formed on the substrate and including an opening surrounding each of the emitters; a conductive extraction grid formed on the dielectric layer and including an opening surrounding each of the emitters; and an oblong focus electrode surrounding the linear array of emitters.
- 2. The baseplate of claim 1, further comprising a resistor formed on the substrate, the resistor having a first terminal coupled to the emitters and a second terminal that is coupled to a source of electrons.
- 3. The baseplate of claim 1 wherein the linear array of emitters comprises two or more emitters.
- 4. The baseplate of claim 1 wherein the linear array of emitters comprises a plurality of emitters arranged in a row having a width of one emitter or more.
- 5. The baseplate of claim 1 wherein the linear array of emitters comprises a plurality of emitters arranged in a single row having a width of one emitter.
- 6. The baseplate of claim 1 wherein the linear array of emitters comprises a plurality of emitters arranged in two adjacent rows, wherein the emitters are staggered between the two adjacent rows.
- 7. The baseplate of claim 1 wherein the substrate comprises silicon.
- 8. The baseplate of claim 1 wherein the focusing electrode is electrically connected to the emitters.
- 9. The baseplate of claim 1 wherein the focusing electrode is electrically coupled to the emitters.
- 10. The baseplate of claim 9, further including an element chosen from the group consisting of: a bias resistor, a constant current element and a constant voltage drop element, the element electrically coupling the focusing electrode to the emitters.
- 11. A field emission display baseplate, comprising:
a substrate; an emitter formed on the substrate; a dielectric layer formed on the substrate and having an opening formed about the emitter; a conductive extraction grid formed on the dielectric layer and having an opening formed about the emitter; a focus electrode formed on the substrate and having an opening formed above the emitter; and an impedance element electrically coupled between the focus electrode and the emitter.
- 12. The baseplate of claim 11 wherein the substrate comprises silicon.
- 13. The baseplate of claim 11 wherein the impedance element is chosen from a group consisting of: a bias resistor, a constant current element and a constant voltage drop element.
- 14. The baseplate of claim 11 wherein the focus electrode comprises:
a polysilicon focus electrode; and a dielectric supporting structure formed on the extraction grid.
- 15. The baseplate of claim 14 wherein the dielectric supporting structure has a thickness of between five and ten microns.
- 16. A field emission display baseplate, comprising:
a substrate; an emitter formed on the substrate, the emitter being electrically coupled to a first node; a dielectric layer formed on the substrate and having an opening formed about the emitter; a conductive extraction grid formed on the dielectric layer and having an opening formed about the emitter; a focus electrode formed on the substrate and having an opening formed above the emitter, the focus electrode being electrically coupled to the first node; an impedance element electrically coupled between the focus electrode and the emitter; and a current source coupled to the first node.
- 17. The baseplate of claim 16 wherein the substrate comprises silicon.
- 18. The baseplate of claim 16 wherein the impedance element comprises a bias resistor.
- 19. The baseplate of claim 16 wherein the impedance element comprises a constant current element.
- 20. The baseplate of claim 16 wherein the impedance element comprises a constant voltage drop element.
- 21. The baseplate of claim 16 wherein the focus electrode comprises:
a polysilicon focus electrode; and a dielectric supporting structure formed on the extraction grid.
- 22. The baseplate of claim 22 wherein the dielectric supporting structure has a thickness of between five and ten microns.
- 23. A field emission display comprising:
a baseplate comprising:
a substrate; an emitter formed on the substrate; a dielectric layer formed on the substrate and having an opening formed about the emitter; a conductive extraction grid formed on the dielectric layer and having an opening formed about the emitter; and a focusing electrode formed on the substrate and having an opening formed above the emitter such that the focusing electrode physically confines electrons emitted from the emitter; and a faceplate comprising:
a transparent insulating viewing layer; a transparent conductive layer formed on the transparent viewing layer; and a cathodoluminescent layer formed on the transparent conductive layer, the faceplate positioned with the cathodoluminescent layer towards the substrate.
- 24. The display of claim 23 wherein the focus electrode comprises:
a polysilicon focusing electrode; and a dielectric supporting structure formed between the extraction grid and the polysilicon focusing electrode.
- 25. The display of claim 23 wherein the dielectric supporting structure has a thickness of between five and ten microns.
- 26. The display of claim 23 wherein the focusing electrode is electrically connected to the emitter.
- 27. The display of claim 23 wherein the substrate comprises silicon.
- 28. The display of claim 23, further comprising an impedance element coupled between the focus electrode and the emitter.
- 29. The display of claim 28 wherein the impedance element is chosen from a group consisting of: a bias resistor, a constant current element and a constant voltage drop element.
- 30. A field emission display comprising:
a baseplate comprising:
a substrate; a linear array of emitters formed on the substrate; a dielectric layer formed on the substrate and including an opening surrounding each of the emitters; a conductive extraction grid formed on the dielectric layer and including an opening surrounding each of the emitters; and a focus electrode including an oblong opening surrounding the emitters, the focus electrode being electrically coupled to the emitters; and a faceplate comprising:
a transparent insulating viewing layer; a transparent conductive layer formed on the transparent insulating viewing layer; and a cathodoluminescent layer formed on the transparent conductive layer, wherein the faceplate is positioned with the cathodoluminescent layer adjacent the substrate.
- 31. The display of claim 30 wherein the focus electrode is electrically connected to the emitters.
- 32. The display of claim 30 wherein the substrate comprises silicon.
- 33. The display of claim 30, further comprising an impedance element coupled between the focus electrode and the emitters.
- 34. The display of claim 30 wherein the impedance element is chosen from a group consisting of: a bias resistor, a constant current element and a constant voltage drop element.
- 35. The display of claim 30 wherein the emitters comprise a linear array of emitters arranged in a row having a width of two emitters or less.
- 36. The baseplate of claim 30 wherein the emitters comprise a linear array of emitters arranged in a single row having a width of one emitter.
- 37. The display of claim 30 wherein the focus electrode comprises:
a polysilicon focus electrode; and a dielectric supporting structure formed on the extraction grid.
- 38. The display of claim 37 wherein the dielectric supporting structure has a thickness of one micron or less.
- 39. A computer system comprising:
a central processing unit; a memory device coupled to the central processing unit, the memory device storing instructions and data for use by the central processing unit; an input interface; and a display comprising:
a baseplate comprising:
a substrate; a linear array of emitters formed on a surface of the substrate; a dielectric layer formed on the substrate, the dielectric layer having an opening surrounding each of the emitters; a conductive extraction grid formed on the dielectric layer, the extraction grid substantially in a plane defined by tips of the emitters and having an opening surrounding a tip of a respective one of the emitters; and an oblong focus electrode surrounding the emitters; and a faceplate comprising:
a transparent insulating viewing surface; a transparent conductor formed on the transparent viewing surface; and a cathodoluminescent layer formed on the conductive transparent layer.
- 40. The computer system of claim 39 wherein the focus electrode is electrically coupled to the emitters.
- 41. The computer system of claim 39 wherein the emitters are arranged in two adjacent rows.
- 42. The computer system of claim 39 wherein the emitters are staggered between two adjacent rows.
- 43. A method of operating a field emission display comprising:
emitting electrons from a first emitter; and focusing the stream of electrons emitted from the first emitter with a first focus electrode that is electrically coupled to the first emitter and that physically confines the stream of electrons.
- 44. The method of claim 43, further comprising setting the voltage on the first focus electrode to be a function of a first bias current through the first emitter.
- 45. The method of claim 43, further comprising setting a voltage on the first focus electrode to be equal to a voltage on the first emitter.
- 46. The method of claim 45, further comprising steps of:
emitting electrons from a second emitter; and focusing the electrons emitted from the second emitter with a second focus electrode that is electrically coupled to the second emitter and that physically confines the stream of electrons from the second emitter.
- 47. The method of claim 46, further comprising setting the voltage on the second focus electrode to be equal to a voltage on the second emitter.
- 48. A method for operating a field emission display, comprising:
supplying electrons to an emitter from a current source; emitting the electrons from the emitter; focusing the emitted electrons by a focus electrode; intercepting a portion of the emitted electrons; returning the intercepted portion of the emitted electrons to the emitter; and accelerating a non-intercepted portion of the emitted electrons towards a faceplate.
- 49. The method of claim 48 wherein returning a current including the intercepted portion of the emitted electrons to the emitter comprises returning a current including the intercepted portion of the emitted electrons to the emitter via an impedance element.
- 50. The method of claim 48 wherein intercepting a portion of the emitted electrons comprises intercepting a portion of the emitted electrons by the focus electrode.
- 51. The method of claim 48, further comprising setting a voltage on the focus electrode to be equal to the emitter voltage minus the current including the intercepted portion of the emitted electrons times the impedance element impedance.
- 52. The method of claim 48 wherein:
returning a current including the intercepted portion of the emitted electrons to the emitter comprises returning a current including the intercepted portion of the emitted electrons to the emitter via an impedance element; and intercepting a portion of the emitted electrons comprises intercepting a portion of the emitted electrons by the focus electrode, and the method further comprises:
setting a voltage on the focus electrode to be equal to the emitter voltage minus the current including the intercepted portion of the emitted electrons times the impedance element impedance.
- 53. A method of operating a field emission display, the method comprising:
emitting electrons from an emitter; focusing the emitted electrons with a focus electrode; intercepting a portion of the emitted electrons; returning the intercepted portion of the emitted electrons to the emitter through an impedance element; and accelerating a non-intercepted portion of the emitted electrons towards a faceplate.
- 54. The method of claim 53 wherein intercepting a portion of the emitted electrons comprises intercepting a portion of the emitted electrons with the focus electrode.
- 55. The method of claim 53 wherein returning a current including the intercepted portion of the emitted electrons comprises returning a current including the intercepted portion of the emitted electrons to the emitter via a resistor.
- 56. The method of claim 53 wherein returning a current including the intercepted portion of the emitted electrons comprises returning a current including the intercepted portion of the emitted electrons to the emitter via a constant current element.
- 57. The method of claim 53 wherein returning a current including the intercepted portion of the emitted electrons comprises returning a current including the intercepted portion of the emitted electrons to the emitter via a constant voltage drop element.
- 58. The method of claim 53, further comprising setting a bias voltage on the focus electrode to be equal to the emitter voltage minus the current including the intercepted portion of the emitted electrons times the impedance element impedance.
- 59. The method of claim 53, further comprising supplying electrons to the emitter from a current source.
GOVERNMENT RIGHTS
[0001] This invention was made with government support under Contract No. DABT63-93-C-0025 awarded by Advanced Research Projects Agency (ARPA). The government has certain rights in this invention.
Divisions (1)
|
Number |
Date |
Country |
Parent |
09085333 |
May 1998 |
US |
Child |
09653818 |
Sep 2000 |
US |
Continuations (1)
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Number |
Date |
Country |
Parent |
09653818 |
Sep 2000 |
US |
Child |
09847158 |
May 2001 |
US |