Apparatus and method for estimating and adjusting deviations in an optical system based on wavefront aberrations ascribable to misalignment
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01J-001/20
G01J-001/10
출원번호
US-0415936
(2002-01-17)
우선권정보
JP-2001-283674(2001-09-18)
국제출원번호
PCT/JP02/000284
(2002-01-17)
§371/§102 date
20030505
(20030505)
국제공개번호
WO03/025537
(2003-03-27)
발명자
/ 주소
Suzuki,Jiro
Ando,Toshiyuki
Suzuki,Hiroshi
Wadaka,Shusou
Hirano,Yoshihito
Mikami,Izumi
Matsushita,Tadashi
출원인 / 주소
Mitsubishi Denki Kabushiki Kaisha
대리인 / 주소
Birch, Stewart, Kolasch &
인용정보
피인용 횟수 :
2인용 특허 :
1
초록▼
An optical system deviation estimating apparatus includes an erected/inverted attitude setting means 9 for changing dispositional attitude of an optical system under test, a non-interferometric type wavefront measuring means 10 for measuring wavefronts at the attitudes as set up without resorting to
An optical system deviation estimating apparatus includes an erected/inverted attitude setting means 9 for changing dispositional attitude of an optical system under test, a non-interferometric type wavefront measuring means 10 for measuring wavefronts at the attitudes as set up without resorting to interference phenomenon of light, a polynomial approximation means 15 for expanding measured wavefront values determined by the non-interferometric type wavefront measuring means 10 to a polynomial, an averaging arithmetic means 11 for averaging the measured values derived from output of the non-interferometric type wavefront measuring means 10 or alternatively arithmetic values derived from output of the polynomial approximation means 15, and a polynomial specific coefficient extraction arithmetic means 16 for extracting specific coefficient values of the polynomial.
대표청구항▼
The invention claimed is: 1. An optical system deviation estimating apparatus for measuring wavefront propagating through space after having passed through an optical system under test for thereby estimating deviation quantities of optic disposition in said optical system under test on the basis of
The invention claimed is: 1. An optical system deviation estimating apparatus for measuring wavefront propagating through space after having passed through an optical system under test for thereby estimating deviation quantities of optic disposition in said optical system under test on the basis of the measured wavefront, characterized in that said apparatus comprises a) an erected/inverted attitude setting device for changing dispositional attitude of said optical system under test in order to reduce an aberration in the measured wavefront, b) a non-interferometric type wavefront measuring device for measuring wavefronts, respectively, at the attitudes of said optical system as set up without making use of interference phenomenon of light, c) a polynomial approximation device for expanding measured wavefront values determined by said non-interferometric type wavefront measuring device to a polynomial, d) an averaging arithmetic device for averaging the measured values derived from output of said non-interferometric type wavefront measuring device or alternatively arithmetic values derived from output of said polynomial approximation device, and e) a polynomial specific coefficient extraction arithmetic device for extracting specific coefficient values of said polynomial, characterized in that said averaging arithmetic device is designed for summing and averaging the wavefront values measured, respectively, in the erected attitude state and the inverted attitude state set up relative to the direction of gravity with the aid of said erected/inverted attitude setting means. 2. An optical system deviation estimating apparatus set forth in claim 1, characterized in that said non-interferometric type wavefront measuring device includes a) a collimated light beam generating device for generating a collimated light beam, b) a deflecting device for deflecting said collimated light beam outputted from said collimated light beam generating device toward said optical system under test, c) an imaging device for focusing the light beam having passed through said optical system under test while splitting said light beam, d) an image pickup device disposed on a focal plane of said imaging device, e) a centroid position measuring device for determining centroid positions of focused light intensity spots from the image picked up by said image pickup device, and f) a wavefront inclination arithmetic device for determining an inclination quality of the wavefront on the basis of the centroid positions derived from the output of said centroid position measuring device. 3. An optical system deviation estimating apparatus set forth in claim 2, characterized in that said averaging arithmetic device is designed to average through integration the image outputted from said image pickup device. 4. An optical system deviation estimating apparatus set forth in claim 2, characterized in that said image pickup device includes a charge storing function, and that said averaging arithmetic device averages said values by making use of said charge storing function. 5. An optical system deviation estimating apparatus set forth in claim 2, characterized in that said averaging arithmetic means is designed to average the coordinate values of positions of said focused light intensity spots as determined by said centroid position measuring device. 6. An optical system deviation estimating apparatus set forth in claim 2, characterized in that a reference light source of high luminance and low coherence is employed in said collimated light beam generating device, and that said image pickup device is capable of performing image pickup operation at a high rate. 7. An optical system deviation estimating apparatus set forth in claim 6, characterized in that said collimated light beam generating device includes a light source capable of emitting a spot light beam as said reference light source, and additionally a collimating device for transforming the light beam emitted from said reference light source into a collimated light beam. 8. An optical system deviation estimating apparatus set forth in claim 6, characterized in that said collimated light beam generating device further includes a light source having a luminescent center wavelength in a visible wavelength band as said reference light source. 9. An optical system deviation estimating apparatus set forth in claim 6, characterized in that said collimated light beam generating device further includes a waveguide device for guiding light emitted from said reference light source. 10. An optical system deviation estimating apparatus set forth in claim 6, characterized in that said waveguide device includes a single mode fiber or alternatively a polarization-preserving fiber, and an optical fiber connector having a fiber terminating face polished in a planar surface or alternatively in a spherical surface. 11. An optical system deviation estimating apparatus set forth in claim 6, characterized in that intensity of said reference light source can be adjusted externally. 12. An optical system deviation estimating apparatus set forth in claim 1, characterized in that said polynomial approximation device is designed to expand the measured wavefront values to a polynomial of Zernike form. 13. An optical system deviation adjusting apparatus, characterized in that said deviation adjusting apparatus comprises an optical-element-disposition adjusting device for adjusting optic dispositions of individual optical elements of said optical system under test and is arranged for adjusting the optic dispositions of the optical elements of said optical system under test with the aid of said optical system deviation estimating apparatus set forth in claim 1. 14. An optical system deviation estimating apparatus set forth in claim 1, characterized in that said deviation estimating apparatus further comprises a wavefront error calculating device for arithmetically determining a relation between an assembling adjustment error and a wavefront error, and a wavefront error plotting device for representing said wavefront error outputted from said wavefront error calculating means in an orthogonal coordinates system having coordinate axes, wherein said assembling adjustment error of at least one element is taken along a coordinate axis. 15. An optical system deviation estimating apparatus set forth in claim 1, characterized in that said deviation estimating apparatus further comprises a wavefront error calculating device for arithmetically determining a relation between an assembling adjustment error and a wavefront error, a wavefront error plotting device for representing two factors of said wavefront error outputted from said wavefront error calculating device in a two-dimensional coordinates system having coordinate axes along which said assembling adjustment errors are taken, respectively, that said wavefront error plotting device represents simultaneously two coefficients of a polynomial which are used by said wavefront error calculating device as said wavefront error factors, and that said deviation estimating apparatus further comprises an assembling adjustment error estimating device for estimating assembling adjustment errors on the basis of an intersection between straight lines or alternatively curves representing said wavefront error factors and plotted by said wavefront error plotting device. 16. An optical system deviation estimating apparatus as set forth in claim 1, wherein said erected/inverted attitude setting device is configured to set the optical system under test in an erected attitude state and an inverted attitude state, and the aberration in the measured wavefront is substantially eliminated in accordance with the arithmetic averaging device averaging measured wavefront values in the erected attitude and inverted attitude states, respectively. 17. An optical system deviation estimating apparatus as set forth in claim 16, wherein the substantially eliminated aberration is ascribable to gravitational deformation. 18. A method for estimating a deviation of optical disposition in an optical system, comprising: measuring wavefronts passing through the optical system without resorting to the interference phenomenon of light; expanding values of the measured wavefronts to polynomials; and averaging values of the measured wavefronts or the polynomials, wherein the averaging is performed in such a manner to substantially eliminate aberrations in the measured wavefronts ascribed to at least one of atmospheric fluctuations and gravitational deformations in the optical system, and wherein the averaging includes at least one of: integrating the measured wavefront values for a sufficient integrating time to substantially eliminate aberrations ascribed to atmospheric fluctuations; and summing and averaging the measured wavefront values obtained, respectively, when the optical system is at an erect and invert attitude setting to substantially eliminate aberrations ascribed to gravitational deformation.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (1)
Gowrinathan Sankaran, Spacecraft inertial attitude and rate sensor control system.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.