Optical electric-field pattern generator
First Claim
Patent Images
1. An apparatus for spatially modulating an associated input laser beam, comprising:
- a self-calibrating Michelson interferometer array for modulating an amplitude of the laser beam;
a telescope arranged to image relay the modulated amplitude and an associated modified phase of the laser beam; and
a phase spatial light modulator arranged to receive the modulated amplitude and the associated modified phase and adapted to further phase modulate the laser beam.
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Abstract
The amplitude of an input laser beam is modulated by a two-dimensional array of Michelson interferometers comprised of a phase spatial light modulator, a mirror and a 50/50 light beamsplitter. The array of Michelson interferometers is calibrated by adjusting the path length of one of the interferometer arms. The calibration is maintained with the aid of feedback. The amplitude-modulated beam is then directed successively through a field imaging telescope, a polarization beamsplitter, and a quarter-wave plate before impinging a second phase spatial light modulator. The second spatial light modulator is adjusted to apply the desired phase profile. The beam, which at this point has the desired amplitude and phase profiles, is then again directed through the quarter-wave plate and subsequently reflected off of the polarization beamsplitter, out of the apparatus, and into free space.
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Citations
23 Claims
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1. An apparatus for spatially modulating an associated input laser beam, comprising:
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a self-calibrating Michelson interferometer array for modulating an amplitude of the laser beam;
a telescope arranged to image relay the modulated amplitude and an associated modified phase of the laser beam; and
a phase spatial light modulator arranged to receive the modulated amplitude and the associated modified phase and adapted to further phase modulate the laser beam. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
two arms, with each of the arms having an arm length;
an arm length difference obtained by subtracting one of the arm lengths from the other arm length; and
means for adjusting the arm length difference.
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4. The modulating apparatus as defined in claim 3 further comprising means for calibrating the Michelson interferometer array by determining an amplitude modulation caused by the arm length difference.
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5. The modulating apparatus as defined in claim 4 further comprising:
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means for sensing the arm length difference; and
the adjusting means being responsive to the sensing means, whereby the arm length difference is automatically adjusted to compensate for structural changes during the operation of the modulating apparatus.
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6. The modulating apparatus as defined in claim 5 wherein:
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the laser beam has a coherence length; and
the adjusting means maintains the arm length difference at a value less than the coherence length.
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7. The modulating apparatus as defined in claim 6 wherein:
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the second phase spatial light modulator includes an array of pixels, with each of the pixels being translatable; and
the calibration means includes a calibration pixel included in the second phase spatial light modulator that remains stationary.
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8. The modulating apparatus as defined in claim 7 wherein the adjusting means is comprised of means for translating the mirror relative to the beamsplitter.
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9. The modulating apparatus as defined in claim 7 wherein the adjusting means includes a phase modulator located in one of the arms.
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10. The modulating apparatus as defined in claim 8 wherein the sensing means is responsive to an intensity of a light ray reflected off of the calibration pixel.
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11. The modulating apparatus as defined in claim 1, wherein the telescope further comprises:
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field imaging optics having two lenses for transmitting light from the Michelson interferometer array to the phase spatial light modulator;
each of the two lenses having a focal length and the two focal lengths having a sum; and
the two lenses being separated by the sum of the two focal lengths.
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12. The modulating apparatus as defined in claim 11 further comprising:
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means for coupling the laser beam out of the modulating apparatus; and
the coupling means being located in between the field imaging optics and the phase spatial light modulator.
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13. The modulating apparatus as defined in claim 11 further comprising coupling means for transmitting the laser beam from the field imaging optics to the phase spatial light modulator, and also for directing the laser beam out of the modulating apparatus.
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14. The modulating apparatus as defined in claim 13 wherein the coupling means is comprised of a quarter-wave plate and a polarizing beamsplitter.
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15. A method for spatially modulating a laser beam having an amplitude and a phase, comprising:
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creating wave interference to modulate the amplitude of the laser beam by a self-calibrating Michelson interferometer array;
image relaying the modulated amplitude and an associated modified phase of the laser beam; and
modulating the phase of the image relayed laser beam by means of a phase spatial light modulator. - View Dependent Claims (16, 17, 18, 19, 20, 21, 22, 23)
forming two component beams, a first component beam and a second component beam, by passing the laser beam through a beamsplitter;
reflecting the first component beam off of a mirror, with the first component beam traversing a first arm between the beamsplitter and the mirror; and
reflecting the second component beam off of a second phase spatial light modulator, with the second component beam traversing a second arm between the beamsplitter and the second phase spatial light modulator.
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17. The modulating method defined in claim 16 wherein the step of modulating the phase includes transmitting the laser beam onto the phase spatial light modulator after the first and second component beams have respectively traversed the first and second arms.
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18. The modulating method defined in claim 17 wherein subtracting the first arm from the second arm composes an arm difference, comprising varying one of the arms in order to adjust the arm difference.
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19. The modulating method defined in claim 18 comprising:
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sensing the arm difference; and
varying one of the arms responsive to the arm difference.
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20. The modulating method defined in claim 18 comprising calibrating the arm difference by varying one of the arms until a calibration ray has an intensity which is either a maximum or a minimum.
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21. The modulating method defined in claim 17 comprising coupling the laser beam into free space after modulating the phase.
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22. The modulating method defined in claim 17 wherein the laser beam has a plane of vibration, comprising rotating the plane of vibration.
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23. The modulating method defined in claim 17 wherein the laser beam has a lateral cross section, comprising varying the lateral cross section after the amplitude has been modulated.
Specification
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Current AssigneeLawrence Livermore National Security LLC (Government of the United States of America)
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Original AssigneeRegents of the University of California (University of California)
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InventorsStappaerts, Eddy A.
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Primary Examiner(s)Schwartz, Jordan M.
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Assistant Examiner(s)STULTZ, JESSICA T
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Application NumberUS09/819,124Publication NumberTime in Patent Office805 DaysField of Search250/201.9, 356/450, 356/491, 356/345, 359/577, 359/238, 359/239, 359/245, 359/263, 359/277, 359/276, 359/278, 359/279, 359/296, 359/315, 359/318, 359/197, 359/212, 359/284US Class Current359/239CPC Class CodesG02B 26/0841 the reflecting element bein...
