IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
UP-0603071
(2003-06-24)
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등록번호 |
US-7627251
(2009-12-16)
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발명자
/ 주소 |
- Walther, Frederick G.
- Roth, Jeffrey M.
- Keicher, William E.
- DeCew, Alan E.
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출원인 / 주소 |
- Massachusetts Institute of Technology
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대리인 / 주소 |
Hamilton, Brook, Smith & Reynolds, P.C.
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인용정보 |
피인용 횟수 :
6 인용 특허 :
14 |
초록
▼
A communication device uses one or two stacks of reflective deflectors to steer the electromagnetic waves carrying signals received and transmitted through a single telescope/aperture device. The signals outside the device may be circularly polarized while inside the device they are linearly polariz
A communication device uses one or two stacks of reflective deflectors to steer the electromagnetic waves carrying signals received and transmitted through a single telescope/aperture device. The signals outside the device may be circularly polarized while inside the device they are linearly polarized most of the time. The deflectors within each stack are transparent to the signals steered by the deflectors behind them. Since the deflecting wave band may shift with the changing angle of incidence of the signals due to steering, the wave bands are sufficiently spaced apart. When the signals impact the deflectors at nearly normal angles, the wave bands can be made more narrow. When more than one stack of deflectors is used, the spacing between the wave bands within one stack may be utilized by another stack. Beam splitters and a variety of other optical devices (such as quarter wave plates, half wave plates, Faraday rotators, and equivalent devices) are used to separate signals for further processing within the device. Instead of reflective deflectors, the device may generally use stacks of transmissive deflectors for similar effect in a similar way.
대표청구항
▼
What is claimed is: 1. A communication device comprising: an aperture structure; and wavelength dependent deflectors deflecting respective electromagnetic signals of respective wavelengths at different respective wavelength dependent angles to simultaneously, dynamically and independently steer the
What is claimed is: 1. A communication device comprising: an aperture structure; and wavelength dependent deflectors deflecting respective electromagnetic signals of respective wavelengths at different respective wavelength dependent angles to simultaneously, dynamically and independently steer the electromagnetic signals passing through the aperture structure in different wavelength dependent angular directions through free space to or from remote receiver or transmitter devices at different angular locations. 2. A device of claim 1 further comprising an aperture linear/circular polarization device between at least one of the deflectors and the aperture structure. 3. A device of claim 1 wherein at least one of the deflectors is movable. 4. A device of claim 1 wherein the deflectors form a first stack, a deflector in the first stack passing a signal deflected by another deflector in the first stack. 5. A device of claim 4 wherein at least one deflector in the first stack deflects substantially all signals within a wavelength band. 6. A device of claim 5 wherein individual deflectors in the first stack deflect substantially all signals each within its respective non-overlapping wavelength band and pass signals deflected by other deflectors in the first stack. 7. A device of claim 6 wherein at least one of the deflectors in the first stack is movable and reflects signals at nearly normal incidence. 8. A device of claim 6 wherein the deflectors in the first stack are reflectors. 9. A device of claim 4 wherein individual deflectors in the first stack pass signals deflected by other deflectors in the first stack. 10. A device of claim 1 wherein electromagnetic signals deflected by at least one of the deflectors carry communications transmitted by the device and communications received by the device. 11. A device of claim 1 wherein the aperture structure is a telescope. 12. A device of claim 1 wherein the device transmits and/or receives wavelength division multiplexing electromagnetic signals. 13. A method for communication comprising: passing electromagnetic signals through an aperture structure; and deflecting respective electromagnetic signals of respective wavelengths at different respective angles, by wavelength dependent deflectors to simultaneously dynamically and independently steer the electromagnetic signals passing through the aperture structure in different wavelength dependent angular directions through free space to or from remote receiver or transmitter devices at different angular locations. 14. A method of claim 13 further comprising changing type of polarization of electromagnetic signals using an aperture linear/circular polarization device positioned between at least one of the deflectors and the aperture structure. 15. A method of claim 13 wherein at least one of the deflectors is movable. 16. A method of claim 13 wherein the deflectors form a first stack, a deflector in the first stack passing a signal deflected by another deflector in the first stack. 17. A method of claim 16 wherein at least one deflector in the first stack deflects substantially all signals within a wavelength band. 18. A method of claim 17 wherein individual deflectors in the first stack deflect substantially all signals each within its respective non-overlapping wavelength band and pass signals deflected by other deflectors in the first stack. 19. A method of claim 18 wherein at least one of the deflectors in the first stack is movable and reflects signals at nearly normal incidence. 20. A method of claim 18 wherein the deflectors in the first stack are reflectors. 21. A method of claim 16 wherein individual deflectors in the first stack pass signals deflected by other deflectors in the first stack. 22. A method of claim 13 wherein electromagnetic signals deflected by at least one of the deflectors carry communications transmitted by the device and communications received by the device. 23. A method of claim 13 wherein the aperture structure is a telescope. 24. A method of claim 13 further comprising transmitting and/or receiving wavelength division multiplexing electromagnetic signals. 25. A communication device comprising: aperture means; and means for wavelength dependent deflecting of respective wavelength division multiplexing electromagnetic signals of respective wavelengths at different respective angles simultaneously to dynamically and independently steer the electromagnetic signals passing through the aperture means in different wavelength dependent angular directions through free space to or from remote receiver or transmitter devices at different angular locations. 26. A device of claim 25 further comprising means for linear/circular polarization between at least one of means for deflecting and the aperture means. 27. A device of claim 25 wherein at least one of the means for deflecting is movable. 28. A device of claim 25 wherein the means for deflecting form a first stack, each means for deflecting in the first stack passing a signal deflected by another means for deflecting in the first stack. 29. A device of claim 28 wherein at least one means for deflecting in the first stack deflects substantially all signals within a wavelength band. 30. A device of claim 29 wherein individual means for deflecting in the first stack deflect substantially all signals each within its respective non-overlapping wavelength band and pass signals deflected by other means for deflecting in the first stack. 31. A device of claim 30 wherein at least one of the means for deflecting in the first stack is movable and reflects signals at nearly normal incidence. 32. A device of claim 30 wherein the means for deflecting in the first stack are means for reflecting. 33. A device of claim 30 further comprising a second stack of means for deflecting respective electromagnetic signals passing through the aperture structure at respective angles, individual means for deflecting in the second stack deflecting substantially all signals each within its respective non-overlapping wavelength band and passing signals deflected by other means for deflecting in the second stack. 34. A device of claim 33 wherein a wavelength band of at least one means for deflecting of the second stack is located between wavelength bands of two means for deflecting of the first stack and a wavelength band of at least one means for deflecting of the first stack is located between wavelength bands of two means for deflecting of the second stack. 35. A device of claim 28 wherein individual means for deflecting in the first stack pass signals deflected by other means for deflecting in the first stack. 36. A device of claim 28 further comprising: first means for beam splitting according to polarization coupled to the aperture means and the first stack; means for conveying signals coupled to the first means for beam splitting; and first means for linear/circular polarization, positioned so that electromagnetic signals deflected by at least one of the means for deflecting in the first stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the first means for beam splitting, and, before being deflected, first pass through the first means for beam splitting and then pass through the first linear/circular polarization device and, after being deflected, first pass through the first means for linear/circular polarization and then pass through the first means for beam splitting, the means for deflecting in the first stack being means for reflecting. 37. A device of claim 36 further comprising: first means for conveying transmission signals; and first means for conveying received signals, the means for conveying signals receiving from the first means for conveying transmission signals at least one signal carrying communications transmitted by the device and the first means for conveying received signals receiving from the means for conveying signals at least one signal carrying communications received by the device, the electromagnetic signals deflected by at least one of the means for deflecting in the first stack carrying communications transmitted by the device and communications received by the device. 38. A device of claim 36 wherein at least one of the means for deflecting in the first stack is movable. 39. A device of claim 36 further comprising: a second stack comprising means for deflecting respective electromagnetic signals passing through the aperture means at respective angles, the individual means for deflecting in the first stack passing signals deflected by other means for deflecting in the first stack and individual means for deflecting in the second stack passing signals deflected by other means for deflecting in the second stack, the means for deflecting in the second stack being means for reflecting; and second means for linear/circular polarization, positioned so that electromagnetic signals deflected by at least one of the means for deflecting in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the first means for beam splitting, and, before being deflected, first pass through the means for beam splitting and then pass through the second means for linear/circular polarization and, after being deflected, first pass through the second means for linear/circular polarization and then pass through the first means for beam splitting, the direction of polarization of the electromagnetic signals passing through the first means for linear/circular polarization being substantially orthogonal, within the means for conveying signals, to the direction of polarization of the electromagnetic signals passing through the second means for linear/circular polarization. 40. A device of claim 39 further comprising: second means for beam splitting according to polarization coupled to the means for conveying signals; first means for conveying transmission signals; first means for conveying received signals; second means for conveying transmission signals; second means for conveying received signals; first means for conveying polarized signals coupled to the second means for beam splitting; the first means for conveying polarized signals receiving from the first means for conveying transmission signals at least one signal carrying communications transmitted by the device and the first means for conveying received signals receiving from the first means for conveying polarized signals at least one signal carrying communications received by the device; and second means for conveying polarized signals coupled to the second means for beam splitting; the second means for conveying polarized signals receiving from the second means for conveying transmission signals at least one signal carrying communications transmitted by the device and the second means for conveying received signals receiving from the second means for conveying polarized signals at least one signal carrying communications received by the device. 41. A device of claim 28 further comprising: a first means for beam splitting according to polarization coupled to the aperture means and the first stack; a means for conveying signals coupled to first the means for beam splitting; and a first means for polarization rotation, positioned so that electromagnetic signals deflected by at least one of the means for deflecting in the first stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the first means for beam splitting, and, before being deflected, first pass through the first means for beam splitting and then pass through the first means for polarization rotation and, after being deflected, first pass through the first means for polarization rotation and then pass through the first means for beam splitting, the means for deflecting in the first stack being means for reflecting. 42. A device of claim 41 further comprising: first means for conveying transmission signals; and first means for conveying received signals, the means for conveying signals receiving from the first means for conveying transmission signals at least one signal carrying communications transmitted by the device and the first means for conveying received signals receiving from the signal path at least one signal carrying communications received by the device, the electromagnetic signals deflected by at least one of the means for deflecting in the first stack carrying communications transmitted by the device and communications received by the device. 43. A device of claim 41 wherein at least one of the means for deflecting in the first stack is movable. 44. A device of claim 41 further comprising: a second stack comprising means for deflecting respective electromagnetic signals passing through the aperture means at respective angles, the individual means for deflecting in the first stack passing signals deflected by other means for deflecting in the first stack and individual means for deflecting in the second stack passing signals deflected by other means for deflecting in the second stack, the means for deflecting in the second stack being means for reflecting; and a second means for polarization rotation, positioned so that electromagnetic signals deflected by at least one of the means for deflecting in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the first means for beam splitting, and, before being deflected, first pass through the first means for beam splitting and then pass through the second means for polarization rotation and, after being deflected, first pass through the second means for polarization rotation and then pass through the first polarization beam splitter, the direction of polarization of the electromagnetic signals passing through the first means for polarization rotation being substantially orthogonal, within the means for conveying signals, to the direction of polarization of the electromagnetic signals passing through the second means for polarization rotation. 45. A device of claim 44 further comprising: second means for beam splitting according to polarization coupled to the signal path; first means for conveying transmission signals; first means for conveying received signals; second means for conveying transmission signals; second means for conveying received signals; first means for conveying polarized signals coupled to the second means for beam splitting; the first means for conveying polarized signals receiving from the first means for conveying transmission signals at least one signal carrying communications transmitted by the device and the first means for conveying received signals receiving from the first means for conveying polarized signals at least one signal carrying communications received by the device; and second means for conveying polarized signals coupled to the second means for beam splitting; the second means for conveying polarized signals receiving from the second means for conveying transmission signals at least one signal carrying communications transmitted by the device and the second means for conveying received signals receiving from the second means for conveying polarized signals at least one signal carrying communications received by the device. 46. A device of claim 41 further comprising: a second stack comprising means for deflecting respective electromagnetic signals passing through the aperture means at respective angles, the individual means for deflecting in the first stack passing signals deflected by other means for deflecting in the first stack and individual means for deflecting in the second stack passing signals deflected by other means for deflecting in the second stack, the means for deflecting in the second stack being means for reflecting; and means for linear/circular polarization, positioned so that electromagnetic signals deflected by at least one of the means for deflecting in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the first means for beam splitting, and, before being deflected, first pass through the first means for beam splitting and then pass through the means for linear/circular polarization and, after being deflected, first pass through the means for linear/circular polarization and then pass through the first means for beam splitting, the direction of polarization of the electromagnetic signals passing through the first means for polarization rotation being substantially orthogonal, within the means for conveying signals, to the direction of polarization of the electromagnetic signals passing through the means for linear/circular polarization. 47. A device of claim 28 further comprising a second stack comprised of means for deflecting respective electromagnetic signals passing through the aperture means at respective angles, at least one means for deflecting in the second stack passing at least one signal deflected by another means for deflecting in the second stack. 48. A device of claim 47 wherein individual means for deflecting in the first stack pass signals deflected by other means for deflecting in the first stack and individual means for deflecting in the second stack passing signals deflected by other means for deflecting in the second stack. 49. A device of claim 47 further comprising means for beam splitting according to polarization coupled to the first stack, second stack, and the aperture means. 50. A device of claim 25 wherein electromagnetic signals deflected by at least one of the means for deflecting carry communications transmitted by the device and communications received by the device. 51. A device of claim 25 wherein the aperture means is a telescope. 52. A communication device comprising: an aperture structure configured to receive and/or transmit electromagnetic signals; a polarization element configured to alter a polarization of the electromagnetic signals; a polarizing splitting element configured to split the electromagnetic signals into first and second electromagnetic signals based on an altered polarization of the electromagnetic signals; a first stack of deflectors deflecting first respective electromagnetic signals of respective wavelengths at respective angles, individual deflectors in the first stack deflecting substantially all first electromagnetic signals within the individual deflectors' respective non-overlapping wavelength band and passing first electromagnetic signals deflected by other deflectors in the first stack, with at least one deflector in the first stack deflecting substantially all first signals within a wavelength band; a second stack of deflectors defecting second respective electromagnetic signals of respective wavelengths at respective angles, individual deflectors in the second stack deflecting substantially all second electromagnetic signals within the individual deflectors' respective non-overlapping wavelength band and passing second electromagnetic signals deflected by other deflators in the second stack, with at least one deflector in the second stack deflecting substantially all second electromagnetic signals within a wavelength band; a first polarization rotation device positioned so that the first electromagnetic signals pass through the first polarization rotation device before being deflected by the first stack of deflectors and, after being deflected, pass through the first polarization rotation device and then pass through the polarizing splitting element; and a second polarization rotation device positioned so that the second electromagnetic signals pass through the second polarization rotation device before being deflected by the second stack of deflectors and, after being deflected, pass through the second polarization rotation device and then pass through the polarizing splitting element. 53. A device of claim 52 wherein at least one second stack deflectors' wavelength band is located between two first stack deflectors' wavelength bands and at least one first stack deflectors' wavelength band is located between two second stack deflectors' wavelength bands. 54. A communication device comprising: an aperture structure; a stack of deflectors deflecting respective electromagnetic signals of respective wavelengths at respective angles, the electromagnetic signals passing through the aperture structure, a defector in the stack passing a signal deflected by another deflector in the stack; a polarization beam splitter coupled to the aperture structure and the stack; a signal path coupled to the polarization beam splitter; and a linear/circular polarization device, positioned so that electromagnetic signals deflected by at least one of the deflectors in the stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, pass through the polarization beam splitter and then pass through the linear/circular polarization device and, after being deflected, pass through the linear/circular polarization device and then pass through the polarization beam splitter, the deflectors in the stack being reflectors. 55. A device of claim 54 further comprising: a transmission path; and a reception path, the signal path receiving from the transmission path at least one signal carrying communications transmitted by the device and the reception path receiving from the signal path at least one signal carrying communications received by the device, the electromagnetic signals deflected by at least one of the deflectors in the stack carrying communications transmitted by the device and communications received by the device. 56. A device of claim 54 wherein at least one of the deflectors in the stack is movable. 57. A device of claim 54 further comprising: a second stack of deflectors deflecting respective electromagnetic signals passing through the aperture structure at respective angles, the individual deflectors in the stack passing signals deflected by other deflectors in the stack and individual deflectors in the second stack passing signals deflected by other deflectors in the second stack, the deflectors in the second stack being reflectors; and a second linear/circular polarization device, positioned so that electromagnetic signals deflected by at least one of the deflectors in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, pass through the polarization beam splitter and then pass through the second linear/circular polarization device and, after being deflected, pass through the second linear/circular polarization device and then pass through the polarization beam splitter, the direction of polarization of the electromagnetic signals passing through the linear/circular polarization device being substantially orthogonal, within the signal path, to the direction of polarization of the electromagnetic signals passing through the second linear/circular polarization device. 58. A device of claim 57 further comprising: a second polarization beam splitter coupled to the signal path; a first transmission path; a first reception path; a second transmission path; a second reception path; a first polarized path coupled to the second polarization beam splitter; the first polarized path receiving from the first transmission path at least one signal carrying communications transmitted by the device and the first reception path receiving from the first polarized path at least one signal carrying communications received by the device; and a second polarized path coupled to the second polarization beam splitter; the second polarized path receiving from the second transmission path at least one signal carrying communications transmitted by the device and the second reception path receiving from the second polarized path at least one signal carrying communications received by the device. 59. A communication device comprising: an aperture structure; a stack of deflectors deflecting respective electromagnetic signals of respective wavelengths at respective angles, the electromagnetic signals passing through the aperture structure, a defector in the stack passing a signal deflected by another deflector in the stack; a polarization beam splitter coupled to the aperture structure and the stack; a signal path coupled to the polarization beam splitter; and a polarization rotation device, positioned so that electromagnetic signals deflected by at least one of the deflectors in the stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, pass through the polarization beam splitter and then pass through the polarization rotation device and, after being deflected, pass through the polarization rotation device and then pass through the polarization beam splitter, the deflectors in the stack being reflectors. 60. A device of claim 59 further comprising: a transmission path; and a reception path, the signal path receiving from the transmission path at least one signal carrying communications transmitted by the device and the reception path receiving from the signal path at least one signal carrying communications received by the device, the electromagnetic signals deflected by at least one of the deflectors in the stack carrying communications transmitted by the device and communications received by the device. 61. A device of claim 59 wherein at least one of the deflectors in the first stack is movable. 62. A device of claim 59 further comprising: a second stack of deflectors deflecting respective electromagnetic signals passing through the aperture structure at respective angles, the individual deflectors in the stack passing signals deflected by other deflectors in the stack and individual deflectors in the second stack passing signals deflected by other deflectors in the second stack, the deflectors in the second stack being reflectors; and a second polarization rotation device, positioned so that electromagnetic signals deflected by at least one of the deflectors in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, pass through the polarization beam splitter and then pass through the second polarization rotation device and, after being deflected, pass through the second polarization rotation device and then pass through the polarization beam splitter, the direction of polarization of the electromagnetic signals passing through the polarization rotation device being substantially orthogonal, within the signal path, to the direction of polarization of the electromagnetic signals passing through the second polarization rotation device. 63. A device of claim 62 further comprising: a second polarization beam splitter coupled to the signal path; a first transmission path; a first reception path; a second transmission path; a second reception path; a first polarized path coupled to the second polarization beam splitter; the first polarized path receiving from the first transmission path at least one signal carrying communications transmitted by the device and the first reception path receiving from the first polarized path at least one signal carrying communications received by the device; and a second polarized path coupled to the second polarization beam splitter; the second polarized path receiving from the second transmission path at least one signal carrying communications transmitted by the device and the second reception path receiving from the second polarized path at least one signal carrying communications received by the device. 64. A device of claim 59 further comprising: a second stack of deflectors deflecting respective electromagnetic signals passing through the aperture structure at respective angles, the individual deflectors in the stack passing signals deflected by other deflectors in the stack and individual deflectors in the second stack passing signals deflected by other deflectors in the second stack, the deflectors in the second stack being reflectors; and a linear/circular polarization device, positioned so that electromagnetic signals deflected by at least one of the deflectors in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, pass through the polarization beam splitter and then pass through the linear/circular polarization device and, after being deflected, pass through the linear/circular polarization device and then pass through the polarization beam splitter, the direction of polarization of the electromagnetic signals passing through the polarization rotation device being substantially orthogonal, within the signal path, to the direction of polarization of the electromagnetic signals passing through the linear/circular polarization device. 65. A communication device comprising: an aperture structure configured to receive and/or transmit electromagnetic signals; a polarization element configured to alter a polarization of the electromagnetic signals; a polarizing splitting element configured to split the electromagnetic signals into first and second electromagnetic signals based on an altered polarization of the electromagnetic signals; a first stack of deflectors deflecting respective first electromagnetic signals of respective wavelengths at respective angles, individual deflectors in the first stack configured to pass first electromagnetic signals deflected by other deflectors in the first stack; a second stack of deflectors deflecting respective second electromagnetic signals being directed towards, individual deflectors in the second stack configured to pass second electromagnetic signals deflected by other deflectors in the second stack; a first polarization rotation device positioned so that the first electromagnetic signals pass through the first polarization rotation device before being deflected by the first stack of deflectors and, after being deflected, pass through the first polarization rotation device and then pass through the polarizing splitting element; and a second polarization rotation device positioned so that the second electromagnetic signals pass through the second polarization rotation device before being deflected by the second stack of deflectors and, after being deflected, pass through the second polarization rotation device and then pass through the polarizing splitting element. 66. A method for communication comprising: passing of electromagnetic signals by an aperture structure; altering a polarization of the electromagnetic signals; splitting the electromagnetic signals into first and second electromagnetic signals based on an altered polarization state; passing the first electromagnetic signals through a first polarization rotation device; passing the second electromagnetic signals through a second polarization rotation device; deflecting first respective electromagnetic signals of respective wavelengths at respective angles by a first stack of deflectors, the deflecting further comprising: individual deflectors in the first stack deflecting substantially all the first electromagnetic signals each within its respective non-overlapping wavelength band and passing the first electromagnetic signals deflected by other deflectors in the first stack; and deflecting second respective electromagnetic signals at respective wavelengths at respective angles using a second stack of deflectors, the deflecting further comprising: individual deflectors in the second stack deflecting substantially all the second electromagnetic signals each within its respective non-overlapping wavelength band and passing the second electromagnetic signals deflected by other deflectors in the second stack; and passing the first and second electromagnetic signals, after deflection, through the respective first and second polarization rotation devices. 67. A method of claim 66 wherein at least one second stack deflectors' wavelength band is located between two first stack deflectors' wavelength bands and at least one first stack deflectors' wavelength band is located between two second stack deflectors' wavelength bands. 68. A method for communication comprising: passing of electromagnetic signals by an aperture structure; deflecting respective electromagnetic signals of respective wavelengths at respective angles by a stack of deflectors; passing a signal to a deflector in the stack, deflected by another deflector in the stack; coupling a polarization beam splitter to the aperture structure and the stack; coupling a signal path to the polarization beam splitter; and positioning a linear/circular polarization device so that electromagnetic signals deflected by at least one of the deflectors in the stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the first polarization beam splitter, and, before being deflected, first pass through the polarization beam splitter and then pass through the linear/circular polarization device and, after being deflected, pass through the linear/circular polarization device and then pass through the polarization beam splitter, the deflectors in the stack being reflectors. 69. A method of claim 68 further comprising: receiving by the signal path from a first transmission path at least one signal carrying communications transmitted by the device; and receiving by a first reception path from the signal path at least one signal carrying communications received by the device, the electromagnetic signals deflected by at least one of the deflectors in the stack carrying communications transmitted by the device and communications received by the device. 70. A method of claim 68 wherein at least one of the deflectors in the stack is movable. 71. A method of claim 68 further comprising: using a second stack of deflectors to deflect respective electromagnetic signals passing through the aperture structure at respective angles, the individual deflectors in the stack passing signals deflected by other deflectors in the stack and individual deflectors in the second stack passing signals deflected by other deflectors in the second stack, the deflectors in the second stack being reflectors; and positioning a second linear/circular polarization device so that electromagnetic signals deflected by at least one of the deflectors in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, first pass through the polarization beam splitter and then pass through the second linear/circular polarization device and, after being deflected, first pass through the second linear/circular polarization device and then pass through the polarization beam splitter, the direction of polarization of the electromagnetic signals passing through the linear/circular polarization device being substantially orthogonal, within the signal path, to the direction of polarization of the electromagnetic signals passing through the second linear/circular polarization device. 72. A method of claim 71 further comprising: coupling a second polarization beam splitter to the signal path; coupling a first polarized path to the second polarization beam splitter; the first polarized path receiving from a first transmission path at least one signal carrying communications transmitted by the device and a first reception path receiving from the first polarized path at least one signal carrying communications received by the device; and coupling a second polarized path to the second polarization beam splitter; the second polarized path receiving from a second transmission path at least one signal carrying communications transmitted by the device and a second reception path receiving from the second polarized path at least one signal carrying communications received by the device. 73. A method for communication comprising: passing of electromagnetic signals by an aperture structure; deflecting respective electromagnetic signals of respective wavelengths at respective angles by a stack of deflectors; passing a signal to a deflector in the stack, deflected by another deflector in the stack; coupling a polarization beam splitter to the aperture structure and the stack; coupling a signal path to the polarization beam splitter; and positioning a polarization rotation device so that electromagnetic signals deflected by at least one of the deflectors in the stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, first pass through the polarization beam splitter and then pass through the polarization rotation device and, after being deflected, first pass through the polarization rotation device and then pass through the polarization beam splitter, the deflectors in the stack being reflectors. 74. A method of claim 73 further comprising: receiving by the signal path from a first transmission path at least one signal carrying communications transmitted by the device, and receiving by a first reception path from the signal path at least one signal carrying communications received by the device, the electromagnetic signals deflected by at least one of the deflectors in the stack carrying communications transmitted by the device and communications received by the device. 75. A method of claim 73 wherein at least one of the deflectors in the first stack is movable. 76. A method of claim 73 further comprising: deflecting by a second stack of deflectors respective electromagnetic signals passing through the aperture structure at respective angles, the individual deflectors in the stack passing signals deflected by other deflectors in the stack and individual deflectors in the second stack passing signals deflected by other deflectors in the second stack, the deflectors in the second stack being reflectors; and positioning a second polarization rotation device so that electromagnetic signals deflected by at least one of the deflectors in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, first pass through the polarization beam splitter and then pass through the second polarization rotation device and, after being deflected, first pass through the second polarization rotation device and then pass through the polarization beam splitter, the direction of polarization of the electromagnetic signals passing through the polarization rotation device being substantially orthogonal, within the signal path, to the direction of polarization of the electromagnetic signals passing through the second polarization rotation device. 77. A method of claim 76 further comprising: coupling a second polarization beam splitter to the signal path; coupling a first polarized path to the second polarization beam splitter; the first polarized path receiving from a first transmission path at least one signal carrying communications transmitted by the device and a first reception path receiving from the first polarized path at least one signal carrying communications received by the device; and coupling a second polarized path to the second polarization beam splitter; the second polarized path receiving from a second transmission path at least one signal carrying communications transmitted by the device and a second reception path receiving from the second polarized path at least one signal carrying communications received by the device. 78. A method of claim 77 further comprising: deflecting respective electromagnetic signals passing through the aperture structure at respective angles by a second stack of deflectors , the individual deflectors in the stack passing signals deflected by other deflectors in the stack and individual deflectors in the second stack passing signals deflected by other deflectors in the second stack, the deflectors in the second stack being reflectors; and positioning a linear/circular polarization device so that electromagnetic signals deflected by at least one of the deflectors in the second stack, are deflected at nearly normal angle, are linearly polarized when leaving and entering the polarization beam splitter, and, before being deflected, first pass through the polarization beam splitter and then pass through the linear/circular polarization device and, after being deflected, first pass through the linear/circular polarization device and then pass through the polarization beam splitter, the direction of polarization of the electromagnetic signals passing through the polarization rotation device being substantially orthogonal, within the signal path, to the direction of polarization of the electromagnetic signals passing through the linear/circular polarization device.
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