Patent Number: 042007941
Section: claims

1. A combined fine focusing micro lens array and micro deflector assembly for use in electron beam tubes of the fly's eye type comprising a fine focusing micro lens array sub-assembly formed by at least one thin planar apertured lens plate fabricated from silicon semiconductor material and having an array of micro lens aperture openings formed therein by photolithographic semiconductor microcircuit fabrication techniques, the apertured silicon lens plate having highly conductive surfaces and being secured to glass rods for holding the lens plate in parallel spaced-apart relationship relative to the micro deflector assembly with the plane of the lens plate substantially at right angles with respect to an electron beam path passing through the assembly, the apertures in the silicon lens plate being axially aligned along respective longitudinal axes passing through the center of the respective apertures parallel to the electron beam path and comprising an array of fine focusing lens elements, said combined fine focusing micro lens array and micro deflector assembly further including a micro deflector sub-assembly mounted immediately adjacent to said fine focusing micro lens array sub-assembly and defining a honeycomb matrix of sets of orthogonally disposed micro deflector elements there being a set of orthogonally disposed micro deflector elements axially aligned with each respective fine focusing lens element along a respective longitudinal axis for deflecting an electron beam passing through the respective fine focusing micro lens array element along orthogonal x-y directional axes of movement in a plane normal to the electron beam path. 2. A combined micro lens array and micro deflector assembly according to claim 1 wherein the fine focusing micro lens array sub-assembly comprises a multiplicity of spaced-apart stacked parallel thin planar apertured lens plates each fabricated from silicon semiconductor and each having an array of aperture openings formed therein, the respective aperture openings in each of the lens plates being axially aligned along a respective longitudinal axis with corresponding aperture openings in the remaining lens plates. 3. A combined micro lens array and micro deflector assembly according to claim 2 wherein said honeycomb matrix of sets of micro deflector elements are comprised by orthogonally arrayed interdigited sets of parallel spaced-apart deflector bars which define the respective orthogonally arrayed sets of micro deflector elements with alternate bars of each set of deflector bars being interconnected electrically for common connection to a respective source of fine x-y deflection potential. 4. A combined micro lens array and micro deflector assembly according to claim 3 wherein each of the thin planar apertured lens plates comprise thin single crystalline silicon wafers having lens aperture openings etched through nondoped areas thereof by a suitable etchant which attacks the nondoped areas of the wafer where the aperture openings are to be formed but does not attack highly doped surface areas of the wafer where no aperture openings are to be formed, said highly doped surface areas being formed by diffusionof a suitable dopant into the surface of the wafer to a suitable thickness of the order of 2 to 4 microns dependent upon the thickness of the wafer with subsequent exposure of the wafer to the etchant to thereby form an array of fine focusing lens aperture openings of precise dimension and exceptional symmetry on each wafer. 5. A combined micro lens array and micro deflector assembly according to claim 4 wherein after completion of etching of the matrix of aperture openings in each of the thin single crystalline silicon plates all the way through the thickness of the plate, the remaining planar surface area of the plate is left with highly conductive characteristics due to the heavy diffusion of a dopant such as boron into the remaining planar surface area to provide the desired differential etching characteristics required during etching formation of the aperture openings. 6. A combined micro lens array and micro deflector assembly according to claim 5 wherein each of the thin planar apertured lens plates comprises a thin planar wafer of single crystalline silicon about 2 microns thick having a matrix of aperture openings formed therein by etching from one side only all the way through the thickness of the wafer at precise points defined by the masking area formed on the surface of the wafer where no aperture openings are to exist with the masked area being impervious to the etchant employed in forming the aperture openings. 7. A combined micro lens array and micro deflector assembly according to claim 5 wherein the thin planar apertured lens plates each comprise a thin planar single crystalline silicon wafer of about 178 millimeter thickness etched from each of the opposite planar sides thereof through appropriately formed aperture opening areas defined by suitable masking of the surfaces of the wafer where no openings are desired and application of an etchant to both sides of the wafer. 8. A combined micro lens array and micro deflector assembly according to claim 5 wherein the dopant is boron and the etchant is a pyrocatechol ethylene diamine. 9. A combined micro lens array and micro deflector assembly according to claim 5 wherein the orthogonally arrayed sets of parallel spaced-apart deflector bars are comprised of elongated flat bars of polycrystalline silicon having a metalized surface. 10. A combined micro lens array and micro deflector assembly according to claim 9 wherein the planar apertured silicon lens plates comprising the micro lens array are held together in stacked parallel assembled relationship by spaced-apart glass rod supports whose longitudinal axes extend at right angles to the plates and to which the planar silicon lens plates are secured near their periphery and wherein the two orthogonally arrayed sets of parallel spaced-apart deflection bars comprising the sets of micro deflector elements are held in assembled spaced-apart parallel relationship by respective sets of spaced-apart parallel supporting glass rods whose longitudinal axes extend in a plane parallel to the plane of the deflector bars but at right angles thereto and to which the ends of the deflector bars are thermally bonded. 11. A combined micro lens array and micro deflector assembly according to claim 10 further including respective annularly-shaped outer support rings for the micro lens array sub-assembly and for the micro deflector sub-assembly comprised of molybdenum, tungsten or some other suitable material and to which the glass support rods of the respective sub-assembly are secured by fusion or otherwise. 12. A combined micro lens array and micro deflector assembly according to claim 11 further including electrically conductive termination plate means mounted parallel to said stacked parallel spaced-apart silicon plates and having apertures formed therein axially aligned with the array of micro lens elements formed by the aligned apertures in the stacked parallel thin silicon lens plates and with the micro defector elements, said termination plate means being mounted on the entrance side of the micro lens array relative to the direction of an electron beam projected through the assembly, said termination plate means being secured to and supported by an outer support ring in common with said micro lens array for mounting said termination plate means and said micro lens array in assembled relation with said micro deflector sub-assembly. 13. A combined micro lens array, micro deflector and target assembly according to claim 12 further including a planar target electrode member fabricated from silicon semi-conductor material mounted in a plane parallel to said thin apertured silicon plates and to the plane of said deflector bars and axially spaced apart therefrom in a direction extending along the path of an electron beam exiting the assembly after passing therethrough, said target electrode member being secured at its outer peripheral edge to an outer support ring used in mounting the target electrode member in assembled relation with the micro lens array and micro deflector sub-assemblies. 14. A combined micro lens array, micro deflector and target assembly according to claim 13 wherein the support ring secured in common to said termination plate means and said fine focusing micro lens array, the support ring secured to said micro deflector sub-assembly and the support ring secured to the target electrode member all in turn are secured at their peripheral edges to additional axially extending glass supporting rods whose longitudinal axes extend at right angles to the planes of the termination plate, the micro lens array, the micro deflector sub-assembly and the target electrode member. 15. A combined fine focusing micro lens array and micro deflector assembly according to claim 14 wherein the annularly-shaped outer support rings for each of the fine focusing micro lens array sub-assembly and the micro deflector sub-assembly have suitable locating notches formed in the peripheries thereof for maintaining axial alignment of the lens aperture openings in the thin silicon lens plates during assembly and for maintaining axial alignment of the micro deflector lens elements with the respective fine focusing micro lens aperture openings during assembly of the two sub-assemblies, the support rings for the termination plate and the target electrode member also including locating notches for maintaining axial alignment of these members with the micro lens array and micro deflector sub-assemblies. 16. A combined micro lens array and micro deflector assembly according to claim 14 wherein proper axial alignment of the aperture openings in the thin silicon lens plates of the micro lens array sub-assembly and the respective aligned set of micro deflector elements is obtained by light optical or electron optical alignment techniques together with proper axial alignment with the aperture openings in the termination plate and with the target electrode member. 17. A combined micro lens array and micro deflector assembly according to claim 16 wherein the thin planar apertured silicon lens plates and the fine deflector bars are thermally bonded to the glass support rods by electron beam heating or laser beam heating and fusion jointure. 18. A combined micro lens array and micro deflector assembly according to claim 14 wherein electrical connection to the thin apertured silicon lens plates of the micro lens array sub-assembly is obtained by trapping an exposed portion of a conductive wire between the hot glass of at least one of the support glass rods and the conductive surface of the respective lens plate during thermal bonding of the lens plates to the glass support rods and electrical connection to respective bars of the micro deflector sub-assembly is obtained by thermally bonding a thin flat conductive wire to the ends of alternate deflector bars at respective ends of each set of deflector bars. 19. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein each of the thin planar apertured lens plates comprises a thin planar wafer of single crystalline silicon about 1 to 2 microns thickness having a matrix of aperture openings formed therein of about 1-2 microns diameter by etching from one side only all the way through the thickness of the wafer at precise points defined by a masking area formed on the surface of the wafer where no aperture openings are to exist with the masked area being impervious to the etchant employed in forming the aperture openings. 20. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein the thin planar apertured lens elements each comprise a thin planar single crystalline silicon wafer of about 1/2 millimeter thickness etched from each of the opposite planar sides thereof through openings defined by a masking area formed on both planar surfaces of the wafer where no openings are to be formed and application of a suitable etchant to both sides of the wafer. 21. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein the planar apertured silicon lens plates comprising the micro lens array are held together in stacked parallel assembled relationship by spaced-apart glass rod supports whose longitudinal axes extend at right angles to the plates and to which the planar silicon lens plates are secured at their periphery. 22. A combined micro lens array and micro deflector assembly according to claim 21 further including respective annularly-shaped outer support rings for the micro lens array sub-assembly and for the micro deflector sub-assembly comprised of molybdenum, tungsten or some other suitable material and to which the glass support rods of the respective sub-assembly are secured by thermal bonding or otherwise. 23. A combined fine focusing micro lens array and micro deflector assembly according to claim 22 wherein the annularly-shaped outer support rings for each of the fine focusing micro lens array sub-assembly and the micro deflector sub-assembly have suitable locating notches formed in the peripheries thereof for maintaining axial alignment of the lens aperture openings in the thin silicon lens plates during assembly and for maintaining axial alignment of the micro deflector lens elements with the respective fine focusing micro lens aperture openings during assembly of the two sub-assemblies. 24. A combined micro lens array and micro deflector assembly according to claim 21 wherein proper axial alignment of the aperture openings in the thin silicon lens plates of the micro lens array sub-assembly and the respective aligned set of micro deflector elements is obtained by light optical or electron optical alignment techniques. 25. A combined micro lens array and micro deflection assembly according to claim 1 or 3 further including electrically conductive termination plate means mounted parallel to said silicon lens plate and having apertures formed therein axially aligned with the array of micro lens elements formed by the apertures in the thin silicon lens plate and the axially aligned micro deflector elements, said termination plate means being mounted on the entrance side of the micro lens array relative to the direction of an electron beam projected through the assembly. 26. A combined micro lens array, micro deflector and target assembly according to claim 1 or 3 further including a planar target electrode member fabricated from silicon semi-conductor material mounted in a plane parallel to said thin apertured silicon plates and to the plane of said deflector bars and axially spaced apart therefrom in a direction extending along the path of an electron beam exiting the assembly after passing therethrough. 27. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein said fine focusing micro lens array and said micro deflector sub-assembly are secured in assembled relation by axially extending glass support rods whose longitudinal axes extend at right angles to the plane of micro lens array and the plane of the micro deflector sub-assemblies. 28. A combined micro lens array and micro deflector assembly according to claim 27 wherein the thin planar apertured silicon lens plates and the fine deflector bars are thermally bonded to the glass support rods by electron beam heating or laser beam heating and fusion jointure. 29. A combined micro lens array and micro deflector assembly according to claim 27 wherein the stacked parallel array of thin apertured silicon lens plates comprising the micro lens array are held in spaced-apart parallel relationship by a common set of axially extending glass support rods to which the lens plates are directly secured and whose longitudinal axes extend at right angles to the plane of the lens plates and wherein the micro deflector sub-assembly is held in assembled relationship by respective sets of glass support rods which have the longitudinal axis thereof extend in a plane parallel to the plane of the deflection bars but at right angles thereto and to which the ends of the respective sets of deflector bars are thermally bonded, the deflector bars are comprised of elongated flat bars of polycrystalline silicon having a metalized surface, and the glass support rods to which the deflector bars are secured are in turn secured in common to the same set of axially extending glass support rods holding the apertured silicon lens plates for mounting the micro deflector sub-assembly in juxtaposed parallel relationship to said micro lens array. 30. A combined micro lens array and micro deflector assembly according to claim 29 wherein the end deflector bars only of each set of deflector bars is comprised of malleable metal such as tungsten and have extensions extending beyond the point of connection to the glass rods supporting the deflector bars in assembled relation, said extensions being shaped to form mounting tabs for securing the micro deflector sub-assembly to the axially extending glass support rods with the micro lens array in juxtaposed parallel relation thereto. 31. A combined micro lens array and micro deflector assembly according to claim 29 wherein the ends of the common set of axially extending glass support rods are shaped to seat with and support the bonded to a precision insulating sapphire ball that in turn is seated in and thermally bonded to a socket formed in an annularly-shaped support ring for mounting the assembly within the housing of a fly's eye type electron beam tube. 32. A combined micro lens array and micro deflector assembly according to claim 31 further including an electrically conductive termination plate mounted parallel to said thin apertured silicon lens plates and having apertures formed therein axially aligned with the array of micro lens elements formed by the axially aligned apertures in the stacked spaced-apart parallel silicon lens plates and with the micro deflector elements, said termination plate being mounted directly to the common set of axially extending glass support rods used to hold the combined micro lens array and micro deflector assembly in assembled relation on the entrance side of the assembly relative to the direction of an electron beam travelling therethrough, and further including a planar target electrode member secured to the common set of axially extending glass support rods parallel to the thin apertured silicon lens plates and the plane of the deflector bars and spaced apart therefrom in a direction extending along the path of an electron beam exiting the assembly after passing therethrough. 33. A combined micro lens array and micro deflector assembly according to claim 29 wherein electrical connection to the thin apertured silicon lens plates of the micro lens array sub-assembly is obtained by trapping an exposed portion of a conductive wire between the hot glass of at least one of the support glass rods and the conductive surface of the respective lens plate during thermal bonding of the lens plates to the glass support rods and electrical connection to the respective bars of the micro deflector sub-assembly is obtained by thermally bonding a thin flat conductive wire to the ends of alternate deflector bars at respective ends of each set of deflector bars. 34. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein electrical connection to at least one of the thin apertured silicon lens plates of the micro lens array sub-assembly is obtained by trapping an exposed portion of a conductive wire between the hot glass of at least one of the glass support rods and the conductive surface of the respective plate during thermal bonding of the plates to the glass support rods with the conductive wire thereafter being connected by conventional lead-in insulated conductor to a source of electrical energy. 35. A combined micro lens array according to claim 34 wherein the exposed portion of the conductive wire is formed from a material which alloys with silicon. 36. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein the glass support rods at the point of thermal bonding to the silicon lens plates have suitable projections extending inwardly to contact the peripheral edge portions of the silicon plates at the point of connection whereby the effective insulator distance between the adjacent silicon plates can be made to be much greater than the plate separation distance. 37. A combined micro lens array and micro deflector assembly according to claim 36 wherein the inwardly extending projection comprises inwardly extending glass branches extending substantially normal to the main trunk of the vertically extending glass support rods. 38. A combined micro lens array and micro deflector assembly according to claim 36 wherein the glass support rods themselves are bent or shaped outwardly away from the point of connection thereof to the thin apertured silicon lens plates whereby greater insulator spacing is achieved between adjacent silicon plates in comparison to the plate separation distance. 39. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein the aperture openings formed in at least one side of one of the thin apertured silicon lens plates are not round but are semi-elliptical in configuration for reducing third order aberrations. 40. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein ring-shaped pads of increased thickness compatible material are secured to points around the periphery of the thin silicon apertured lens plates for increasing the thickness thereof, and a plurality of insulating ball spacers are seated in the ring-shaped pads for assembling the thin silicon lens plates in a stacked spaced-apart parallel array upon being clamped together in a self-supporting structure. 41. A combined micro lens array and micro deflector assembly according to claim 1 or 3 wherein a plurality of support holes are formed around the peripheral edge portion of at least one of the thin silicon apertured lens plates and a plurality of small insulating ball spacers are seated in the holes for providing an insulating mounting means for the respective thin silicon lens plate. 42. A combined micro lens array and micro deflector assembly according to claim 1 or 3 further including a planar target member of electron sensitive material removably mounted by a vacuum-tight enclosure housing in common with and in a plane parallel to said thin apertured micro lens silicon plates and to the plane of said micro deflector bars and axially spaced apart therefrom in a direction extending along the path of an electron beam exiting the assembly after passing therethrough. 43. A fine focusing micro lens array sub-assembly for use in electron beam tubes of the fly's eye type comprising at least one thin planar apertured lens plate fabricated from silicon semiconductor material and having a matrix of aperture openings formed therein by photolithographic semiconductor microcircuit fabrication techniques, the apertured silicon lens plate having highly conductive surfaces and being secured near the periphery to glass support rods for holding the plate in parallel spaced-apart relationship with the apertures axially aligned in parallel with a longitudinal axis passing through the center of the plate to form an array of fine focusing lens elements for an electron beam, the glass support rods having the longitudinal axes thereof extending at right angles to the plane of the thin apertured silicon lens plate and being thermally bonded thereto. 44. A fine focusing micro lens array sub-assembly according to claim 43 wherein the thin apertured silicon lens plate comprises a thin planar wafer of single crystalline silicon about 2 microns thick and having a matrix of aperture openings formed therein by etching from one side only all the way through the thickness of a starting wafer at precise points defined by a masking area formed on the surface of the wafer where no aperture openings are to exist with the masked area being impervious to the etchant employed in forming the aperture openings. 45. A combined micro lens array and micro deflector assembly according to claim 43 wherein the fine focusing micro lens array sub-assembly comprises a multiplicity of spaced-apart stacked parallel thin planar apertured lens plates each fabricated from silicon semiconductor and each having an array of aperture openings formed therein, the respective aperture openings in each of the lens plates being axially aligned along a respective longitudinal axis with corresponding aperture openings in the remaining lens plates. 46. A fine focusing micro lens array sub-assembly according to claim 45 wherein the thin apertured silicon lens plates comprise a thin planar single crystalline silicon wafer of about 1/2 millimeter thickness etched all the way through from both of the opposite planar sides thereof through openings defined by a masking area formed on both planar surfaces of the wafer where no openings are desired and application of a suitable etchant to the unmasked areas on both sides of the wafer. 47. A fine focusing micro lens array sub-assembly according to claim 43 or 45 wherein each of the thin apertured silicon lens plates comprise a thin single crystalline silicon wafer having lens aperture openings etched through nondoped areas thereof by a suitable etchant which attacks the nondoped areas of the wafer where the aperture openings are to be formed but does not attack highly doped surface areas of the wafer where no aperture openings are to be formed, said highly doped surface areas being formed by diffusion of a suitable dopant into the surface of the wafer to a thickness of the order of 2 to 4 microns dependent upon the thickness of the wafer with subsequent exposure of the wafer to the etchant to thereby form an array of fine focusing lens aperture openings of precise dimension and exceptional symmetry on each wafer. 48. A micro lens array sub-assembly according to claim 47 wherein after completion of etching of the matrix of aperture openings in each of the thin single crystalline silicon plates all the way through the thickness of the plates, the remaining planar surface area of the plate is left with highly conductive characteristics due to the heavy diffusion of a dopant such as boron into the remaining planar surface area to provide the desired differential etching characteristics required during etching formation of the aperture openings. 49. A micro lens array sub-assembly according to claim 48 wherein each of the thin apertured silicon lens plates comprises a thin planar wafer of single crystalline silicon about 2 microns thick and having a matrix of aperture openings formed therein by etching from one side only all the way through the thickness of the wafer at precise points defined by the masking area formed on the surface of the wafer where no aperture openings are to exist with the masked surface areas being impervious to the etchant employed in forming the aperture openings. 50. A micro lens array sub-assembly according to claim 48 wherein the thin planar apertured lens plates each comprise a thin planar single crystalline silicon wafer of about 1/2 millimeter thickness etched from each of the opposite planar sides thereof through photolithographically formed aperture opening areas defined by suitable masking of the surfaces of the wafer where no aperture openings are desired and application of an etchant to both sides of the wafer. 51. A micro lens array sub-assembly according to claim 48 wherein the dopant is boron and the etchant is pyrocatechol ethylene diamine. 52. A micro lens array sub-assembly according to claim 51 further including an annularly-shaped outer support ring for the micro lens array sub-assembly comprised of molybdenum, tungsten or other suitable metal with the glass support rods being thermally bonded to the inner peripheral edge portions thereof and with the support ring of metal having suitable locating notches formed in the periphery thereof for maintaining axial alignment of the sub-assemblies with other sub-assemblies comprising a fly's eye electron beam tube. 53. A micro lens array sub-assembly according to claim 43 or 45 wherein electrical connection to the thin apertured silicon lens plates is obtained by trapping an exposed portion of a thin conductive wire between the hot glass of at least one of the glass support rods and the conductive surface of the respective plate during thermal bonding of the plates to the glass support rods with the conductive wire thereafter being connected by conventional lead-in insulated conductor to a source of electric energy. 54. A micro lens array sub-assembly according to claim 43 or 45 wherein the glass support rods at the point of thermal bonding to the thin silicon lens plates have suitable projections extending inwardly to contact the peripheral edge portions of the silicon plates at the point of connection whereby the effective insulator distance between silicon plates and other parts can be made to be much greater than the plate separation distance. 55. A micro lens array sub-assembly according to claim 43 or 45 wherein the aperture openings formed in at least one side of one of the thin apertured silicon lens plates are not round but are semi-elliptical in configuration for reducing third order aberrations. 56. A micro lens array sub-assembly according to claim 43 or 45 wherein ring-shaped thickened pads of compatible conductive material are secured to points around the peripheral edge portions of the thin silicon apertured lens plates for increasing the thickness thereof and a plurality of insulating ball spacers are seated in the ring-shaped pads for assembling the thin silicon lens plates in a stacked spaced-apart parallel array upon being clamped together in a self-supporting structure. 57. A micro lens array sub-assembly according to claim 43 or 45 wherein a plurality of support holes are formed around the periphery of the thin silicon apertured lens and a plurality of small insulating ball spacers are seated in and thermally bonded to the holes for providing an insulating mounting means for the respective lens plates. 58. A micro deflector sub-assembly for use in electron beam tubes of the fly's eye type comprising a honeycomb matrix of sets of orthogonally disposed micro deflector elements there being a set of orthogonally disposed micro deflector elements axially aligned with each respective electron beam path for deflecting an electron beam along orthogonal x-y directional axes of movement in a plane normal to the electron beam path, said honeycomb matrix of sets of micro deflector elements being comprised by two orthogonally arrayed sets of two interdigited parallel spaced-apart deflector bars which define the respective orthogonally arrayed sets of micro deflector elements with alternate bars of each set of deflector bars being interconnected electrically for common connection to a respective source of fine x-y deflection potential and each of said deflector bars being fabricated from silicon and having a highly conductive surface formed thereon. 59. A micro deflector assembly according to claim 58 wherein the silicon deflector bars comprise polycrystalline silicon. 60. A micro deflector assembly according to claim 58 wherein the two orthogonally arrayed sets of parallel spaced-apart silicon deflector bars comprising the micro deflector elements are held in assembled spaced-apart parallel relationship by respective sets of spaced-apart parallel supporting glass support rods whose longitudinal axes extend in a place parallel to the plane of the sets of parallel spaced-apart deflector bars but at right angles to the longitudinal extent of the bars and with the ends of the deflector bars being thermally bonded to the glass support rods. 61. A micro deflector sub-assembly according to claim 60 wherein at least the end of the end deflector bars of each set of deflector bars is comprised of a metal such as tungsten and extend beyond the point of connection to the glass support rods holding the deflector bars in assembled relation, said extensions being shaped to form mounting tabs for mounting the micro deflector sub-assembly in a fly's eye electron beam tube. 62. A micro deflector sub-assembly according to claim 60 further including an outer annularly-shaped support ring comprised of molybdenum, tungsten or other suitable material to which the parallel supporting glass support rods are thermally bonded for mounting the micro deflector sub-assembly in a fly's eye electron beam tube. 63. A micro deflector sub-assembly according to claim 60 wherein the micro deflector sub-assembly is held in assembled relationship with other sub-assemblies and components of the fly's eye electron beam tube by an additional set of axially extending glass support rods which have the longitudinal axis thereof extend at right angles to the plane of the deflector bars. 64. A micro deflector sub-assembly according to claim 63 wherein the first mentioned parallel supporting glass support rods extend to and engage the axially extending glass support rods and are thermally bonded thereto. 65. A micro deflector sub-assembly according to claim 63 wherein at least the end of the deflector bars of each set of deflector bars is comprised of a malleable metal such as tungsten and extend beyond the point of connection to the parallel supporting glass rods, said malleable metal extension being bent over to engage and thermally bond to respective axially extending glass support rods. 66. A micro deflector sub-assembly according to claim 63 further including an annularly-shaped support ring comprised of molybdenum, tungsten or other suitable material to which the parallel supporting glass rods are bonded at different points around the inner periphery thereof, the axially extending glass support rods being thermally bonded to the metal support ring at different points around the outer periphery thereof. 67. The method of fabricating micro lens array plates from round, thin planar single crystalline silicon semiconductor wafers of about 1/2 millimeter thickness or less comprising the steps of: (a) growing a wet silicon dioxide layer on both flat planar surfaces of the silicon wafer to a thickness of several hundred Angstrom units;  (b) by photolithographic techniques employing a photo-resist and solvent for silicon dioxide form an array of silicon dioxide dots on both surfaces of the silicon wafer where it is desired that aperture openings be formed with the centers of each set of opposing silicon dioxide dots on the opposite surfaces of the silicon wafer being axially aligned on a common axis passing through both centers and perpendicular to the plane of the wafer;  (c) spin coat a boron containing emulsion over both silicon dioxide dotted flat surfaces of the wafer and fire wafer in a nitrogen atmosphere at substantially 1100.degree. C., to thereby grow a heavily boron doped layer of about 2 microns thickness in surface areas of wafer where it is desired that no aperture openings be formed;  (d) remove excess boron containing emulsion in a hydrofluoride bath and remove silicon dioxide dots in a fresh hydrofluoride bath to leave a deep heavily boron doped and highly conductive layer of about 2 microns thickness in those planar surface areas on both sides of the wafer where it is desired that no apertures be formed interspersed with an array of dotted updoped silicon surface areas where it is desired that apertures be formed;  (e) etching the wafer in an etchant comprising a hot pyrocatechol and ethylene diamine bath which attacks the dotted undoped silicon surface areas of the wafer previously protected by the silicon dioxide dots during the boron doping step at a faster differential rate than it attacks the boron doped surface areas; and  (f) continuing the etching until an array of lens aperture openings of a desired diameter have been formed all the way through the thickness of the wafer by the meeting of the simultaneously etched pockets produced on both sides of the wafer by the differential etching action of the etchant on the dotted undoped silicon surface areas.  (a) growing a wet silicon dioxide layer on one flat planar surface to a thickness of several hundred Angstrom units;  (b) by photolithographic techniques employing a photo resist and solvent for silicon dioxide produce an array of silicon dioxide dots where it is desired that aperture openings be formed on one side only of the wafer;  (c) by photolithographic techniques employing a photo resist and solvent for silicon dioxide produce an enlarged area of unmasked silicon on the backside of the wafer corresponding to the area of desired aperture openings on the first mentioned side while leaving a substantial peripheral area of silicon dioxide masked silicon around the peripheral edges of the wafer;  (d) spin coat a boron containing emulsion over silicon dioxide masked surfaces of both sides of the wafer and fire the wafer in a nitrogen atmosphere at about 1100.degree. C. to thereby grow a heavily boron doped layer of about 2 microns thickness through those surface areas of the wafer where it is desired that no aperture openings be formed;  (e) remove excess boron containing emulsion in a hydrofluoric bath and remove silicon dioxide mask in a fresh hydrofluoric bath to leave a deep heavily doped and highly conductive layer of about 2 microns thickness in those planar surface areas of the wafer where it is desired that no apertures be formed interspersed with an array of dotted undoped silicon surface areas where it is desired that apertures be formed;  (f) etching the wafer in an etchant comprising a hot pyrocatechol and ethylene diamine bath which attacks the undoped silicon surface areas of the wafer previously protected by the silicon dioxide dots during the boron doping step at a faster differential rate than it attacks the boron doped surface areas; and  (g) continuing the etching action until an array of lens aperture openings of a desired diameter have been formed all the way through the thickness of the wafer by the differential etching action of the etchant on the dotted undoped silicon surface areas while leaving a substantial peripheral portion of the original starting wafer thickness to provide rigidity to the resultant lens plate. 68. The method according to claim 67 wherein the size of the dots of silicon dioxide formed on one flat planar surface of the silicon wafer is greater than the size of the silicon dioxide dots formed on the opposite surface thereby resulting in an array of aperture openings through the micro lens array plate which have a greater dimension on one side of the plate than the aperture openings on the opposite side. 69. The method according to claim 67 wherein the shape of the silicon dioxide dots formed on opposite flat planar surfaces of the silicon wafer are differently shaped resulting in the formation of an array of aperture openings through the wafer whose shape on one side of the wafer are substantially different from the shape of the aperture openings on the opposite side. 70. The product of the method of fabrication according to claim 67. 71. The product of the method of fabrication according to claim 68. 72. The product of the method of fabrication according to claim 69. 73. The product according to any of claim 67 or 68 or 69 wherein alignment marks are provided on portions of the starting silicon wafer to facilitate alignment of the plates during aperture formation using the photolithographic masks and during subsequent thermal bonding of the apertured plates to glass support rods. 74. The method of fabricating micro lens array plates from round, thin planar single crystalline silicon semiconductor wafers of about 1/2 millimeter thickness comprising the steps of: 75. The product of the method of fabrication according to claim 74. 76. The method according to claim 74 wherein alignment marks are provided on the starting silicon wafer to facilitate alignment of the plates during aperture formation using the photolithographic masks and during subsequent thermal bonding of the aperture plates to glass support rods.