IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0515089
(2003-05-12)
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등록번호 |
US-7265712
(2007-09-04)
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국제출원번호 |
PCT/US03/014612
(2003-05-12)
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§371/§102 date |
20041112
(20041112)
|
국제공개번호 |
WO03/098384
(2003-11-27)
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발명자
/ 주소 |
- Merkel,Kristian
- Cole,Zachary
- Rupavatharam,Krishna
- Babbitt,William R.
- Wagner,Kelvin
- Chang,Tiejun
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
8 인용 특허 :
8 |
초록
▼
Techniques for analog processing of high time-bandwidth-product (TBP) signals use a material with an inhomogeneously broadened absorption spectrum including multiple homogeneously broadened absorption lines. A first set of signals on optical carriers interact in the material during a time on the ord
Techniques for analog processing of high time-bandwidth-product (TBP) signals use a material with an inhomogeneously broadened absorption spectrum including multiple homogeneously broadened absorption lines. A first set of signals on optical carriers interact in the material during a time on the order of a phase coherence time of the homogeneously broadened absorption lines to record an analog interaction absorption spectrum. Within a time on the order of a population recovery time for a population of optical absorbers it the material, the interaction absorption spectrum in the material is read to produce a digital readout signal. The readout signal represents a temporal map of the interaction absorption spectrum, and includes frequency components that relate to a processing result of processing the first set of signals. The techniques allow processing of RADAR signals for improved range resolution to a target, as well as speed of the target, among other uses.
대표청구항
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What is claimed is: 1. A method of processing large bandwidth signals over long times, resulting in high time-bandwidth-product (TBP) signal processing, comprising the steps of: causing a first plurality of signals on optical carriers to interact in a material with an inhomogeneously broadened abso
What is claimed is: 1. A method of processing large bandwidth signals over long times, resulting in high time-bandwidth-product (TBP) signal processing, comprising the steps of: causing a first plurality of signals on optical carriers to interact in a material with an inhomogeneously broadened absorption spectrum including a plurality of homogeneously broadened absorption lines during about a phase coherence time of the homogeneously broadened absorption lines to record an interaction absorption spectrum; and within about a population recovery time for a population of optical absorbers in the material, reading the interaction absorption spectrum to produce a readout signal that represents a temporal map of the interaction absorption spectrum, wherein the readout signal includes frequency components that relate to a processing result of processing the first plurality of signals. 2. The method of claim 1, wherein the material has an inhomogeneously broadened absorption spectrum with a bandwidth greater than about one GigaHertz (109 Hz) and homogeneously broadened absorption lines with bandwidths less than about 100 kiloHertz (105 Hz), for processing signals with a TBP greater than 104. 3. The method of claim 2, wherein a TBP of a first signal in the first plurality of signals is greater than 104. 4. The method of claim 1, said step of reading the interaction absorption spectrum in the material to produce a readout signal further comprising measuring absorption of a frequency chirped optical signal directed into the material. 5. The method of claim 1, said step of reading absorption of the frequency claim 1, wherein the readout signal is produced with a bandwidth substantially less than a minimum bandwidth of the first plurality of signals. 6. The method of claim 1, wherein the readout signal is produced with a bandwidth less than about ten MegaHertz (107 Hz). 7. The method of claim 1, said step of reading the interaction absorption spectrum further comprising modulating an optical carrier to produce a modulated optical signal that includes a component for which frequency sweeps in time across a frequency band within the inhomogeneously broadened absorption spectrum; directing the modulated optical signal on the material; and measuring the optical absorption in time. 8. The method of claim 1, wherein: said step of causing the first plurality of signals to interact further comprises directing the first plurality of signals on the optical carriers along a first spatial mode in the material to record the interaction absorption spectrum that represents a multiplication of spectra of the first plurality of signals; and said readout signal includes frequency components that relate to the results of correlating the first plurality of signals. 9. The method of claim 8, further comprising determining a time delay between two signals in the first plurality of signals based on the readout signal. 10. The method of claim 9, wherein: a first signal of the first plurality of signals represents a RADAR transmitted signal; a second signal of the first plurality of signals represents a received reflected signal based on the RADAR transmitted signal reflected from a target; the method further comprises determining a range to the target based on the time delay between the first signal and the second signal. 11. The method of claim 9, wherein: a first signal of the first plurality of signals represents a first component received at a first antenna element of an antenna array; a second signal of the first plurality of signals represents a second component received at a second antenna element of the antenna array; the method further comprises determining an angle of arrival of a signal received at the antenna array based on the time delay between the first signal and the second signal. 12. The method of claim 8, further comprising, before a first time on the order of the population recovery time expires after the first plurality of signals, performing the step of directing an additional plurality of signals on optical carriers, of one or more additional pluralities of signals, along the first spatial mode in the material at a second time after an immediately previous plurality of signals, to integrate in the interaction absorption spectrum an additional spectrum that represents a multiplication of spectra of the additional plurality of signals. 13. The method of claim 12, wherein: said step of directing the additional plurality of signals along the first spatial mode includes directing the additional plurality of signals which have a particular time delay that is substantively similar to a time delay in the first plurality of signals; said step of reading the interaction absorption spectrum produces a readout signal with a particular value for certain frequency components that are related to the particular time delay; and the particular value is enhanced relative to other values for other frequency components that are related to time delays that are substantively different from the particular time delay. 14. The method of claim 13, wherein: a first signal of each plurality of signals represents a RADAR transmitted signal; and a second signal of each plurality of signals represents a received reflected signal based on the RADAR transmitted signal reflected from a target. 15. The method of claim 14, wherein the RADAR transmitted signal in each plurality of signals is the same as the RADAR transmitted signal in a different plurality of signals. 16. The method of claim 14, wherein the RADAR transmitted signal in each plurality of signals is different from the RADAR transmitted signal a different plurality of signals. 17. The method of claim 1, said step of causing the first plurality of signals on optical carriers to interact in the material, further comprising the steps of: modulating an optical carrier, tuned to one homogeneously broadened absorption line in the material, to carry each signal of the plurality of signals as a modulated optical signal; and directing each modulated optical signal onto the material with sufficient intensity to record in the material the spectral content of each signal. 18. The method of claim 17, said step of modulating the optical carrier further comprising using an electro-optic modulator (EOM) to perform at least one of analog phase modulation and phase binary encoding of the optical carrier based on an input electrical signal. 19. The method of claim 17, said step of directing each modulated optical signal onto the material with sufficient intensity further comprising amplifying the modulated optical signal and directing an amplified modulated optical signal onto the material. 20. The method of claim 1, wherein: said step of causing the first plurality of signals on optical carriers to interact in the material to record an interaction absorption spectrum further comprising causing the first plurality of signals on optical carriers to interact differently in each spatial mode of a plurality of spatial modes to record a plurality of interaction absorption spectra corresponding to the plurality of spatial modes; and said step of reading the interaction absorption spectrum to produce a readout signal further comprises reading the plurality of interaction absorption spectra to produce a plurality of readout signals corresponding to the plurality of interaction absorption spectra; and wherein each readout signal of the plurality of readout signals includes frequency components that relate to a processing result of processing a plurality of signals in a corresponding spatial mode of the plurality of spatial modes. 21. The method of claim 20, wherein: said step of causing the first plurality of signals on optical carriers to interact differently in each spatial mode of the second plurality of spatial modes further comprising frequency shifting a particular signal from the first plurality of signals by a different frequency shift for each spatial mode of the second plurality of spatial modes; and the method further comprises determining a Doppler shift based on a particular frequency shift applied at a particular spatial mode associated with a particular readout signal of the plurality of readout signals. 22. The method of claim 21, wherein: a first signal of the first plurality of signals represents a RADAR transmitted signal; a second signal of the first plurality of signals represents a received reflected signal based on the RADAR transmitted signal reflected from a target; said step of shifting a particular signal from the first plurality of signals comprises shifting the first signal by a different frequency shift for each spatial mode of the second plurality of spatial modes; and said step of determining the Doppler shift further comprises selecting the particular readout signal that provides a greatest signal strength among a plurality of signal strengths corresponding to the plurality of readout signals. 23. The method of claim 22, further comprises determining a range based on a time delay based on the particular readout signal and determining a velocity based on the Doppler shift. 24. The method of claim 1, wherein: said step of causing the first plurality of signals on optical carriers to interact in the material, further comprises the steps of directing a first beam of the first plurality of signals on optical carriers into the material along a first spatial mode; and directing a different second beam of the first plurality of signals on optical carriers into the material along a different second spatial mode that intersects the first spatial mode inside the material; and said step of reading the interaction absorption spectrum further comprises the steps of: directing a frequency chirp signal along a third spatial mode, phase matched to the first spatial mode and the second spatial mode; and causing an output signal and a replica of the frequency chirp to coherently interfere with each other to produce the readout signal. 25. An apparatus for processing high time-bandwidth-product (TBP) signals, comprising: a signal input port for receiving a signal set of one or more pluralities of input signals; a material with an inhomogeneously broadened absorption spectrum including a plurality of homogeneously broadened absorption lines; a first optical coupler to direct a plurality of modulated optical signals based on each plurality of input signals in the signal set onto the material in a set of one or more spatial modes within about a phase coherence time of a homogeneously broadened absorption line to record an interaction absorption spectrum that represents spectral processing of the plurality of input signals; a source of a probing signal; and a detector to measure, with time, based on the interaction absorption spectrum and the probing signal, a readout signal that represents a temporal map of the interaction absorption spectrum, wherein the readout signal includes frequency components that relate to a processing result of processing the first plurality of signals. 26. The apparatus of claim 25, further comprising an analog-to-digital converter (ADC) to digitize the readout signal. 27. The apparatus of claim 25, said source of the probing signal further comprising a source of a chirped optical signal that spans over time a frequency band in the inhomogeneously broadened absorption spectrum of the material. 28. The apparatus of claim 27, wherein the detector measures the readout signal by measuring light transmitted through the material from the chirped optical signal. 29. The apparatus of claim 27, wherein the detector measures the readout signal by measuring a coherent interaction between a replica of the chirped optical signal and an echo stimulated in the material by the chirped optical signal. 30. The apparatus of claim 25, further comprising a post processor to determine a processing result based on the readout signal. 31. The apparatus of claim 25, further comprising: a first source of an optical carrier tuned to one homogeneously broadened absorption line; and a first modulator optically connected to the source of the optical carrier and connected to the signal input port to output the plurality of modulated optical signals based on each plurality of input signals in the signal set. 32. The apparatus of claim 25, further comprising a second optical coupler to direct the probing signal into the material. 33. The apparatus of claim 31, the source of the probing signal further comprising a second modulator optically connected to the first source to generate the chirped optical signal based on the optical carrier. 34. The apparatus of claim 25, wherein the material has an inhomogeneously broadened absorption spectrum with a bandwidth greater than one GigaHz (109 Hertz) and homogeneously broadened absorption lines with bandwidths less, than about 100 kiloHertz (105 Hz), for processing a signal in the set of one or more pluralities of input signals with a TBP greater than 104. 35. The apparatus of claim 25, wherein the detector has a bandwidth less than about ten MegaHertz (107 Hz). 36. The apparatus of claim 26, wherein the ADC has a bandwidth less than about ten MegaHertz (107 Hz). 37. The apparatus of claim 31, the first source further comprising an external cavity diode laser. 38. The apparatus of claim 31, the first source further comprising a frequency stabilization system in which a tuned frequency is stabilized to a transient spectral hole at a spatial mode in the material different from any spatial mode in the set of one or more spatial modes. 39. The apparatus of claim 31, the first modulator further comprising one or more electro-optic phase modulators. 40. The apparatus of claim 31, further comprising a high bandwidth optical amplifier disposed between the first modulator and the first optical coupler to amplify the plurality of modulated optical signals sufficiently to record spectral content of the plurality of modulated optical signals in the material. 41. The apparatus of claim 25, the first optical coupler further comprising an acousto-optic deflector assembly to direct a frequency shifted optical signal based on an optical signal of the plurality of optical signals into a different spatial mode of the set of one or more spatial modes. 42. The apparatus of claim 25, further comprising a long-life, maintenance-free closed-cycle cryostat to condition the material. 43. The apparatus of claim 25, said detector further comprising a low-bandwidth, low-noise photo-receiver. 44. The apparatus of claim 26, said ADC further comprising a low-bandwidth, high-dynamic-range analog to digital converter. 45. The apparatus of claim 25, wherein the first optical coupler directs each different plurality of input signals from the signal set onto the material to integrate the spectral content of an interaction among each plurality into the interaction absorption spectrum before the interaction absorption spectrum decays. 46. The apparatus of claim 41, the acoustic-optic deflector assembly further comprising an AOD set of one or more acousto-optic deflectors (AODs) configured so that: an optical output path from a first AOD of the AOD set is directed into an input of a second AOD of the AOD set; and an acoustic signal propagates in the second AOD in a direction opposite to a direction that an acoustic signal propagates in the first AOD. 47. The apparatus of claim 46, wherein the first AOD is different from the second AOD. 48. The apparatus of claim 46, wherein the first AOD is the same as the second AOD. 49. A system for processing high time-bandwidth-product (TBP) RADAR signals, comprising: a optical analog processing device comprising: a signal input port for receiving a signal set of one or more pluralities of input signals; a material with an inhomogeneously broadened absorption spectrum including a plurality of homogeneously broadened absorption lines; a first optical coupler to direct a plurality of modulated optical signals based on each plurality of input signals in the signal set onto the material in a set of one or more spatial modes within about a phase coherence time of a homogeneously broadened absorption line to record an interaction absorption spectrum that represents spectral processing of the plurality of input signals; a source of a probing signal; and a detector to measure, with time, based on the interaction absorption spectrum and the probing signal, a readout signal that represents a temporal map of the interaction absorption spectrum, wherein the readout signal includes frequency components that relate to a processing result of processing the first plurality of signals; a RADAR signal conditioner configured for: selecting a first set of one or more signals based on one or more RADAR transmitted signals, and a second set of one or more signals based one or more received signals based on the one or more RADAR transmitted signals after reflection from a target; and sending the first set of signals and the second set of signals to the signal input port of the analog optical processing device; and a processor configured to determine range with high resolution to the target based on the readout signal. 50. The system of claim 49, said processor further configured to determine speed of the target based on a Doppler shift of the second set of signals relative to the first set of signals based on the readout signal. 51. A method of processing large bandwidth signals over long times, resulting in high time-bandwidth-product (TBP) signal processing, comprising the steps of: causing an input signal on an optical carrier to interact in a material with an inhomogeneously broadened absorption spectrum including a plurality of homogeneously broadened absorption lines to record an interaction absorption spectrum; and within about a population recovery time for a population of optical absorbers in the material, reading the interaction absorption spectrum to produce a readout signal that represents a temporal map of the interaction absorption spectrum, wherein the readout signal indicates frequency components of the input signal.
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