CN201173972Y - Bidirectional loop transmitting-receiving telescope of synthetic aperture laser image forming radar - Google Patents

Abstract

The utility model provides a two-way ring circuit transmitting-receiving telescope of a synthetic aperture laser imaging radar. The two-way ring circuit consists of an independent emission channel with an image inverting telescope structure and a receiving channel, wherein a defocusing and emitting space phase position modulating plane plate is arranged inside the emitting channel, a defocusing and receiving space phase position modulating plane plate is arranged inside the receiving channel, the emitting defocusing amount is controlled, the phase position modulating function is emitted, the defocusing amount is received and the phase position modulating function is received. The two-way ring circuit transmitting-receiving telescope adopts the same telescope to realize the laser emission of the space quadratic term phase position additional bias and the removal of the optical defocusing receive of the target echo receiving wave surface phase difference, thereby realizing the synthetic imaging of the synthetic aperture laser imaging radar.

Description

The bidirectional loop transmitting-receiving telescope for synthesis of synthetic aperture laser imaging radar

Technical field

The utility model relates to synthetic aperture laser imaging radar, particularly a kind of bidirectional loop transmitting-receiving telescope for synthesis that is used for synthetic aperture laser imaging radar.Bi-directional ring is made up of the independently transmission channel and the receiving cable of image rotation telescope configuration, is used to connect LASER Light Source, photodetector and telescope.It is dull and stereotyped that the modulation of out of focus and transmitter, phase is set in the transmission channel, and it is dull and stereotyped that the modulation of out of focus and receiving phase is set in the receiving cable.Control emission defocusing amount, transmitter, phase modulating function, reception defocusing amount and receiving phase modulating function, with same telescope can implementation space quadratic term phase place additional biasing Laser emission and eliminate the out of focus optics that target echo receives the corrugated aberration and receive, thereby and produce and suitablely on the radar direction of motion realize the aperture compound imaging with controllable phase place quadratic term course.

Background technology

The principle of synthetic aperture laser imaging radar is taken from the theory of SAR of RF application, is to obtain unique optical imagery Observations Means of centimetre magnitude resolution at a distance.But because short 3-6 the order of magnitude of the wavelength ratio radio frequency of optical frequency wave band, and the yardstick of optical telescope primary mirror is greater than a wavelength 3-6 order of magnitude, its spatial emission and reception and radio frequency transmitted and received the principle difference.

Synthetic aperture laser imaging radar adopts optical telescope as receiving antenna and emitting antenna, and is also different for telescopical requirement during still as echoed signal reception and laser beam emission.Therefore, when adopting same telescope as reception and emitting antenna, telescope must satisfy optics simultaneously and receive requirement and Laser emission requirement, guarantees to produce in echo heterodyne reception signal the phase place quadratic term course of target, to realize the laser aperture compound imaging.

In the optics receiving course, when the reflection echo process of target arrives the optical telescope of synthetic aperture laser imaging radar apart from diffraction, will be along with variable in distance produces different corrugated aberration or wavefront shape, when on the photodetector face, carrying out heterodyne detection with the laser local oscillator laser beam is synthetic by receiving telescope, the corrugated aberration will greatly influence heterodyne photodetection efficient, even cause surveying inefficacy.Therefore we are in the patent application of the off-focusing receiving telescope of synthetic aperture laser imaging radar, a kind of telescopical optical receiver antenna of out of focus of synthetic aperture laser imaging radar has been proposed, adopt the method for telescope out of focus or additional space phase place flat board to overcome the point diffraction wave surface aberration assurance heterodyne detection requirement of echoed signal, and produce phase place quadratic term course on the radar direction of motion of generation echo.

In the Laser emission process, telescope is the diffraction limit emission that needs on the assurance primary mirror bore as the basic demand of laser transmitting antenna, so the wavefront properties of the laser lighting hot spot on the target range depends on telescope emission optical field distribution and diffraction distance.In our patent application of space phase bias emission telescope of synthetic aperture laser imaging radar, the transmitter-telescope of a kind of space quadratic term phase bias structure has been proposed, in transmitter-telescope, place the phase modulation (PM) flat board, control telescopical defocusing amount and position modulating function mutually, can on the laser lighting hot spot of transmitter-telescope, produce an added space phase place quadratic term with respect to former point diffraction wave surface, be used to change the laser lighting wavefront, produce suitable and required target illumination quadratic term wavefront.

Therefore, the core key issue that realizes the bore diameter laser imaging is to realize the Laser emission and the optics reception of different defocusing amounts and different additive phase plate with same optical telescope.

The bore diameter laser imaging at first realizes checking in the laboratory, but these experiments belong to the closely simulation of tiny light beam, does not adopt true optical telescope to receive and emitting antenna.U.S. Raytheon Co. in 2006 and Nuo Ge company have realized airborne Synthetic Aperture Laser Radar test respectively under U.S. national defense Advanced Research Project Agency Net supports, but do not consider the reception corrugated aberration of optical antenna or the influence of wavefront shape, the additional space phase bias when yet not considering the emission of optical antenna.See also following document:

(1)M.Bashkansky，R.L.Lucke，F.Funk，L.J.Rickard，and?J.Reintjes，“Two-dimensional?synthetic?aperture?imaging?in?the?optical?domain，”Optics?Letters，Vol.27，pp1983-1985(2002).

(2)W.Buell，N.Marechal，J.Buck，R.Dickinson，D.Kozlowski，T.Wright，and?S.Beck，“Demonstrationof?synthetic?aperture?imaging?ladar，”Proc.of?SPIE，Vol.5791，PP.152-166(2005).

(3)J.Ricklin，M.Dierking，S.Fuhrer，B.Schumm，and?D.Tomlison，“Synthetic?apertureladar?for?tactical?imaging，”DARPA?Strategic?Technology?Office.

The optical receiving system of a synthetic aperture laser imaging radar mainly is made up of optical telescope, beam synthesis and photodetector.Optical telescope is used to collect the echoed signal corrugated and transfers to photodetector, beam synthesis is used for the space of echoed signal light beam and local oscillator laser beam and closes bundle, and photodetector carries out the optical heterodyne that echoed signal light beam and this machine light beam were surveyed and produced to light intensity.

Summary of the invention

The technical problems to be solved in the utility model is to propose a kind of bidirectional loop transmitting-receiving telescope for synthesis of synthetic aperture laser imaging radar, promptly the out of focus optics of the Laser emission of implementation space phase bias and the echo aberration that disappears receives in same optical telescope, realizes the compound imaging of synthetic aperture laser imaging radar.

Technical solution of the present utility model is as follows:

The core of synthetic aperture laser imaging radar bidirectional loop transmitting-receiving telescope for synthesis of the present utility model is: two-way emission is set between optical telescope, LASER Light Source and photodetector receives loop, in two-way emission reception loop, have independently transmission channel and independently receiving cable, and be the image rotation telescope configuration.Therefore can in the receiving cable of bi-directional ring, carry out telescope emission required out of focus operation or additive phase setting, in transmission channel, carry out transmitter-telescope required out of focus operation and additive phase setting, therefore can realize that the out of focus optics of the Laser emission of additional space phase bias and the echo aberration that disappears receives by enough same optical telescopes, obtain the phase place quadratic term course on suitable and the radar direction of motion that can control, thereby realize the aperture compound imaging.

Concrete technical scheme of the present utility model is:

A kind of bidirectional loop transmitting-receiving telescope for synthesis of synthetic aperture laser imaging radar, be characterized in: the LASER Light Source that comprises synthetic aperture laser imaging radar, along this LASER Light Source emission laser beam is first half-wave plate and first polarization splitting prism successively, described laser beam is divided into reflection and transmitted light beam by first polarization splitting prism, this first polarization splitting prism folded light beam is as the local oscillation laser beam, this local oscillation laser beam returns back arrival and enters the 3rd polarization splitting prism by this first polarization splitting prism output through first quarter-wave plate and by first catoptron, this first polarization splitting prism transmitted light beam is as the emission laser beam, this emission laser beam is successively through the first emission image rotation lenses, the emission defocusing amount, emission space phase modulation (PM) plate, the second emission image rotation lenses, second polarization splitting prism, second quarter-wave plate, telescope ocular, telescope objective and telescope go out entrance pupil directive target, the echo laser beam of this target returns through former road, go out entrance pupil through telescope, telescope objective, telescope ocular, second quarter-wave plate is to described second polarization splitting prism, through again after the reflection and reception the space phase modulation panel, second catoptron, first receives image rotation lenses, receive defocusing amount, second receives image rotation lenses arrives the 3rd polarization splitting prism, described echo laser beam and described local oscillation laser beam close bundle by the 3rd polarization splitting prism, again through second half-wave plate and by the 4th polarization splitting prism polarization spectro, the synthetic light beam that all is the horizontal direction polarization carries out heterodyne reception by first photodetector, all is that the synthetic light beam of vertical direction polarization carries out heterodyne reception by second photodetector;

All polarization splitting prisms are set at the horizontal polarization direction light beam to be passed through and the vertical polarization beam reflection;

The angle of described first quarter-wave plate is arranged so that the local oscillation laser beam that reflects from first polarization splitting prism turns back to polarization on first polarization splitting prism from first catoptron and rotated 90 ° and can directly pass through this first polarization splitting prism;

The angle of described second quarter-wave plate is arranged so that the emission laser beam that sees through second polarization splitting prism through the telescope emission, and the echo of target reflection also turns back to polarization on second polarization splitting prism by the light beam that telescope receives and rotated 90 ° and can be reflected by second polarization splitting prism;

Described telescope objective and telescope ocular are formed the antenna telescope that is used for Laser emission and reception, and the focal length of this telescope objective is f ₁With the focal length of telescope ocular be f ₂, the distance between the back focal plane of telescope ocular and the front focal plane of telescope objective is telescopical defocusing amount: $\mathrm{\Δl}=-\frac{f_1^2}{z+R},$ In the formula: z is the synthetic aperture laser imaging radar range-to-go, and R is the radius-of-curvature of emission beam wave surface on distance Z;

Telescopically go out entrance pupil and be positioned on the outer focal plane of telescope objective, the outer focal plane of described telescopical eyepiece is the telescopical emergent pupil face of going into, and describedly telescopically goes out the entrance pupil face and telescopically goes into the emergent pupil face and be in picture;

The described first emission image rotation lenses and the second emission image rotation lenses are formed an emission 4-f image rotation telescope, emergent pupil plane and the antenna of the second emission image rotation lenses be telescopical goes into the emergent pupil face and overlaps, described emission space position phase modulation panel is placed on the front focal plane of the second emission image rotation lenses, and the focal length of the first emission image rotation lenses and the second emission image rotation lenses is f ₃, the defocusing amount of focal plane was in the middle of described emission 4-f image rotation was telescopical:

${\mathrm{\&Delta;l}}_3=-\frac{f_1^2{f}_3^2}{(Z+R){\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2},$

In the formula: z is the synthetic aperture laser imaging radar range-to-go, and the space phase quadratic term equivalent focal length of this emission space position phase modulation panel is:

$R_3=\frac{f_3^2}{{\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2}F,$ F is the equivalent focal length of space bit phase quadratic term biasing in the formula, $F=\frac{f_1^2}{2z};$

Described first receives image rotation lenses and second receives a reception of image rotation lenses composition 4-f image rotation telescope, the first entrance pupil face that receives image rotation lenses and antenna be telescopical goes into the emergent pupil face and overlaps, described reception space bit phase modulation panel is placed on the telescopical entrance pupil face of this reception 4-f image rotation, and first focal length that receives the image rotation lenses and the second reception image rotation lenses is f ₄, the phase function of described reception space phase modulation panel is:

In the formula: x, y are for receiving the position coordinates of space phase modulation panel, and λ is an optical maser wavelength; Focal plane out of focus in the middle of the perhaps described reception 4-f image rotation telescope, defocusing amount is:

$\mathrm{\&Delta;}{l}_4=\frac{f_1^2{f}_4^2}{\mathrm{<figure-callout\; id="2"\; label="z\; f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">z</figure-callout>}{f}_{}^{}{}_2^2}.$

A kind of bidirectional loop transmitting-receiving telescope for synthesis of synthetic aperture laser imaging radar, be characterized in: the LASER Light Source that comprises synthetic aperture laser imaging radar, along this LASER Light Source emission laser beam is first half-wave plate and first polarization splitting prism successively, described laser beam is divided into reflection and transmitted light beam by first polarization splitting prism, this first polarization splitting prism folded light beam is as the local oscillation laser beam, this local oscillation laser beam returns back arrival and enters the 3rd polarization splitting prism by this first polarization splitting prism output through first quarter-wave plate and by first catoptron, this first polarization splitting prism transmitted light beam is as the emission laser beam, this emission laser beam is successively through the first emission image rotation lenses, the emission defocusing amount, emission space phase modulation (PM) plate, the second emission image rotation lenses, second polarization splitting prism, second quarter-wave plate, telescope ocular, telescope objective and telescope go out entrance pupil directive target, the echo laser beam of this target returns through former road, go out entrance pupil through telescope, telescope objective, telescope ocular, second quarter-wave plate is to described second polarization splitting prism, through again after the reflection and reception the space phase modulation panel, second catoptron, first receives image rotation lenses, receive defocusing amount, second receives image rotation lenses arrives the 3rd polarization splitting prism, described echo laser beam and described local oscillation laser beam close bundle by the 3rd polarization splitting prism, again through second half-wave plate and by the 4th polarization splitting prism polarization spectro, the synthetic light beam that all is the horizontal direction polarization carries out heterodyne reception by first photodetector, all is that the synthetic light beam of vertical direction polarization carries out heterodyne reception by second photodetector;

All polarization splitting prisms are set at the horizontal polarization direction light beam to be passed through and the vertical polarization beam reflection;

The angle of described first quarter-wave plate is arranged so that the local oscillation laser beam that reflects from first polarization splitting prism turns back to polarization on first polarization splitting prism from first catoptron and rotated 90 ° and can directly pass through this first polarization splitting prism;

The angle of described second quarter-wave plate is arranged so that the emission laser beam that sees through second polarization splitting prism through the telescope emission, and the echo of target reflection also turns back to polarization on second polarization splitting prism by the light beam that telescope receives and rotated 90 ° and can be reflected by second polarization splitting prism;

Described telescope objective and telescope ocular are formed the antenna telescope that is used for Laser emission and reception, and the focal length of this telescope objective is f ₁With the focal length of telescope ocular be f ₂, the distance between the back focal plane of telescope ocular and the front focal plane of telescope objective is telescopical defocusing amount Δ l=0; Describedly telescopically go out entrance pupil and be positioned on the outer focal plane of telescope objective, the outer focal plane of described telescopical eyepiece is the telescopical emergent pupil face of going into, and describedly telescopically goes out the entrance pupil face and telescopically goes into the emergent pupil face and be in picture;

The described first emission image rotation lenses and the second emission image rotation lenses are formed an emission 4-f image rotation telescope, emergent pupil plane and the antenna of the second emission image rotation lenses be telescopical goes into the emergent pupil face and overlaps, described emission space position phase modulation panel is placed on the front focal plane of the second emission image rotation lenses, and the focal length of the first emission image rotation lenses and the second emission image rotation lenses is f ₃, the defocusing amount of focal plane was in the middle of described emission 4-f image rotation was telescopical:

$\mathrm{\&Delta;}{l}_3=-\frac{f_1^2{f}_3^2}{(Z+R){\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2},$

In the formula: z is the synthetic aperture laser imaging radar range-to-go, and the equivalent focal length of the space phase quadratic term biasing of the phase modulation function of this emission space position phase modulation panel generation is:

$F=\frac{{\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2}{Z^2}R,$

In the formula: z is the synthetic aperture laser imaging radar range-to-go, and R is the radius-of-curvature of emission beam wave surface on distance Z;

Described first receives image rotation lenses and second receives a reception of image rotation lenses composition 4-f image rotation telescope, the first entrance pupil face that receives image rotation lenses and antenna be telescopical goes into the emergent pupil face and overlaps, described reception space bit phase modulation panel is placed on the telescopical entrance pupil face of this reception 4-f image rotation, and first focal length that receives the image rotation lenses and the second reception image rotation lenses is f ₄, the phase function of described reception space phase modulation panel is:

In the formula: x, y are for receiving the position coordinates of space phase modulation panel, and λ is an optical maser wavelength; Focal plane out of focus in the middle of the perhaps described reception 4-f image rotation telescope, defocusing amount is:

${\mathrm{\&Delta;l}}_4=\frac{f_1^2{f}_4^2}{\mathrm{<figure-callout\; id="2"\; label="z\; f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">z</figure-callout>}{f}_{}^{}{}_2^2}.$

Described first half-wave plate and second half-wave plate can be used quarter-wave plate instead.

Describedly telescopically go out entrance pupil and be positioned on the outer focal plane of telescope objective, be the aperture diaphragm of a reality, or only represent a position.

Technique effect of the present utility model:

The utility model can utilize same optical telescope to realize that the out of focus optics of the Laser emission of additional space phase bias and the echo aberration that disappears receives, obtain the phase place quadratic term course on suitable and the radar direction of motion that can control, realize the compound imaging of synthetic aperture laser imaging radar.

Description of drawings

Fig. 1 is the system schematic of an embodiment of bidirectional loop transmitting-receiving telescope for synthesis of the utility model synthetic aperture laser imaging radar.

Embodiment

The utility model is described in further detail below in conjunction with embodiment and accompanying drawing, but should not limit protection domain of the present utility model with this.

See also Fig. 1 earlier, Fig. 1 is the system schematic of an embodiment of bidirectional loop transmitting-receiving telescope for synthesis of the utility model synthetic aperture laser imaging radar.As seen from the figure, present embodiment is mainly used in Gaussian beam emission and the reception of target Fei Nieer diffraction.Its structure:

LASER Light Source 1 emission laser beam from synthetic aperture laser imaging radar, be first half-wave plate (or quarter-wave plate) 2 and first polarization splitting prism 3 then, a road of this first polarization splitting prism 3 outputs return that the back arrives and by first polarization splitting prism, 3 output local oscillation laser beams as the local oscillation laser beam through first quarter-wave plate 4 and by first catoptron 5, image rotation lenses 6 is launched through first successively as the emission laser beam in another road of these first polarization splitting prism, 3 outputs, emission defocusing amount 7, emission space phase modulation (PM) plate 8, the second emission image rotation lenses 9, second polarization splitting prism 10, second quarter-wave plate 11, telescope ocular 12, telescope objective 13 and telescope go out (going into) pupil 14 directive targets, the echo laser beam is back to described second polarization splitting prism 10 through former road, through again after the reflection and reception space phase modulation panel 15, second catoptron 16, first receives image rotation lenses 17, receive defocusing amount 18, second receives image rotation lenses 19 arrives the 3rd polarization splitting prism 20, described echo laser beam and described local oscillation laser beam close bundle by the 3rd polarization splitting prism 20, again through second half-wave plate (or quarter-wave plate) 21 and by the 4th polarization splitting prism 22, it is divided into the identical receiving beam in two bundle polarization directions, carries out the heterodyne balance by first photodetector 23 and second photodetector 24 respectively and receive.

All polarization splitting prisms are set at the horizontal polarization direction light beam to be passed through and the vertical polarization beam reflection.This paper is reference direction with the horizontal polarization direction.

The angle setting of first half-wave plate (or quarter-wave plate) 2 is to control the spectrophotometric intensity ratio of first polarization splitting prism 3, and the emission light beam light intensity that general requirement sees through is far longer than the local oscillation laser beam light intensity of reflection.

The angle of first quarter-wave plate 4 is arranged so that the local oscillation laser beam that reflects from first polarization splitting prism 3 turns back to polarization on first polarization splitting prism 3 from first catoptron 5 and rotated 90 ° and can directly pass through this first polarization splitting prism 3.

The angle of second quarter-wave plate 11 is arranged so that the emission laser beam that sees through second polarization splitting prism 10 through the telescope emission, and the echo of target reflection also turns back to polarization on second polarization splitting prism 10 by the light beam that telescope receives and rotated 90 ° and can be by 10 reflections of second polarization splitting prism.

The local oscillation laser beam is with the incident of horizontal polarization state and directly by the 3rd polarization splitting prism 20, the echo laser beam is with orthogonal polarization state incident and through 20 reflections of the 3rd polarization splitting prism, therefore, local oscillation laser beam and echo laser beam have carried out light beam by the 3rd polarization splitting prism 20 and have closed bundle, the synthetic light beam of polarized orthogonal is again through 45 ° of second half-wave plate (or quarter-wave plate), 21 rotatory polarization attitudes (perhaps becoming the garden polarization state), carry out polarization spectro through the 4th polarization splitting prism 22, the synthetic light beam that all is the horizontal direction polarization carries out heterodyne reception with first photodetector 23, all is that the synthetic light beam of vertical direction polarization carries out heterodyne reception with second photodetector 24.

Telescope objective 13 and telescope ocular 12 are formed the antenna telescope that is used for Laser emission and reception, and the focal length of establishing telescope objective 13 is f ₁With the focal length of telescope ocular 12 be f ₂, then telescopical enlargement factor is $M=\frac{f_1}{{\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2}.$ Telescopically go out (going into) pupil 14 and be positioned on the outer focal plane of object lens 13, the aperture diaphragm of a reality can be set, can not have diaphragm in kind yet and represent a position, the outer focal plane of telescopical eyepiece 12 is telescopical (going out) the pupil face of going into, and (going out) the pupil face of going into that goes out (going into) pupil face 14 and eyepiece is in picture.

The first emission image rotation lenses 6 and the second emission image rotation lenses 9 are formed an emission 4-f image rotation telescope, and the emergent pupil plane of the second emission image rotation lenses 9 and antenna be telescopical goes into (going out) pupil face and overlap.This emission 4-f image rotation telescope has emission defocusing amount 7, and emission space position phase modulation panel 8 is placed on the front focal plane of the second emission image rotation lenses 9.The focal length of the first emission image rotation lenses 6 and the second emission image rotation lenses 9 is set at f ₃

First receives image rotation lenses 17 and second receives image rotation lenses 19 and forms one and receive 4-f image rotation telescope, and the first entrance pupil face that receives image rotation lenses 17 and antenna be telescopical goes into (going out) pupil face and overlap.This reception 4-f image rotation telescope has the defocusing amount 18 of reception, receives space bit phase modulation panel 15 and is placed on the telescopical entrance pupil face of this reception 4-f image rotation.First focal length that receives the image rotation lenses 17 and the second reception image rotation lenses 19 is set at f ₄

First half-wave plate (or quarter-wave plate) 2, first polarization splitting prism 3, first quarter-wave plate 4, first catoptron 5, the first emission image rotation lenses 6, emission defocusing amount 7, emission space phase modulation (PM) plate 8, the second emission image rotation lenses 9, second polarization splitting prism 10, second quarter-wave plate 11, receive space phase modulation panel 15, second catoptron 16, first receives image rotation lenses 17, receive defocusing amount 18, second receives image rotation lenses 19, the two-way modulation that the 3rd polarization splitting prism 20 and second half-wave plate (or quarter-wave plate) 21 have constituted one 3 port receives transmit loop.Wherein: first half-wave plate (or quarter-wave plate) the 2nd, LASER Light Source incident port, second quarter-wave plate 11 are output of emission laser and echo receiving port, and second half-wave plate (or quarter-wave plate) the 21st is surveyed the light signal output end mouth.

Receive in the transmit loop in two-way modulation, from 10 light paths that have the emission laser beam of first polarization splitting prism, 3 to second polarization splitting prisms, modulation panel 8 can be at the surround of laserscope generation additional space phase place quadratic term, change emission laser lighting wavefront mutually with the emission space position to introduce emission defocusing amount 7.

From 20 light paths that have the echo laser beam of second polarization splitting prism, 10 to the 3rd polarization splitting prisms, introduce to receive space bit phase modulation panel 15 or receive defocusing amount 18 and can carry out equivalent defocus and eliminate the purpose of receiving beam out of focus aberration receiving telescope

In the Laser emission light path, suppose that distance is e for the target illumination light field of z _z(x y), requires at surround generation additional space phase place quadratic term to be

Wherein R is the radius-of-curvature of emission beam wave surface on distance Z.In order to realize this wavefront biasing, the telescopical defocusing amount of antenna is $\mathrm{\&Delta;l}=-\frac{f_1^2}{z+R},$ And the equivalent focal length of space phase quadratic term biasing is $F=\frac{f_1^2}{2z}.$ The defocusing amount 7 of therefore launching the telescopical middle focal plane of 4-f image rotation should be:

${\mathrm{\&Delta;l}}_3=\frac{f_3^2}{{\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2}\mathrm{\&Delta;l},$ Promptly ${\mathrm{\&Delta;l}}_3=-\frac{f_1^2{f}_3^2}{(Z+R){\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2}.$

And the space phase quadratic term equivalent focal length of emission space position phase modulation panel 8 should be:

$R_3=\frac{f_3^2}{{\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2}F,$ Promptly $R_3=\frac{f_1^2{f}_3^2}{2\mathrm{<figure-callout\; id="2"\; label="z\; f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">z</figure-callout>}{f}_{}^{}{}_2^2}.$

In the laser pick-off light path, the some diffraction of target goes out the field intensity wavefront that produces on (going into) pupil 14 at the antenna telescope and generally can be expressed as $\mathrm{E\; exp}\left[j\frac{k}{2}\frac{{(x-s_x)}^2+{(y-s_y)}^2}{z}\right],$ In order to eliminate the quadratic term aberration of incident wavefront, should the telescopical defocusing amount of control antenna reach ${\mathrm{\&Delta;l}}^{\&prime;}=\frac{f_1^2}{z}.$ Therefore, a kind of method is promptly to receive in antenna telescope exit pupil position to place on the telescopical entrance pupil of the image rotation position to receive space phase modulation panel 15, and its phase function is:

Promptly

Another method is to make to receive the middle focal plane out of focus of 4-f image rotation telescope, and defocusing amount 18 should be:

${\mathrm{\&Delta;l}}_4=\frac{f_4^2}{{\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">f</figure-callout>}}_2^2}{\mathrm{\&Delta;l}}^{\&prime;},$ Promptly $\mathrm{\&Delta;}{l}_4=\frac{f_1^2{f}_4^2}{\mathrm{<figure-callout\; id="2"\; label="z\; f"\; filenames="Y20082005594200161.png"\; state="\{\{state\}\}">z</figure-callout>}{f}_{}^{}{}_2^2}$

In addition, emission space position phase modulation panel 8 with receive space bit mutually modulation panel 15 can also carry out the design of other special purpose.For example, can design an emission phase modulating function and produce cylinder Laser emission light beam or/and design the biasing of reception position phase modulating function generation cylinder receiving phase, in synthetic aperture laser imaging radar, to produce the azimuth direction phase place quadratic term course of the separable geometries of range direction and flight orientation direction, reduce the complicacy of imaging algorithm.

The diameter that generally requires the object lens entrance pupil is greater than the object lens diameter, and the eyepiece exit pupil diameter is greater than the eyepiece diameter.

Photodetector generally should be placed on the receiving telescope emergent pupil plane, and photodetector can leave telescope emergent pupil plane certain distance, should adopt the image rotation optical system when photodetector leaves telescope emergent pupil plan range when big.

When the Laser emission light source is fiber laser or fiber amplifier, except collimation uses, laser fiber emission port or be equipped with again on the back focal plane position that the lens focus point can be placed directly in the first emission image rotation lenses 6.When fibre system is used for the optics receiving-member, receive image rotation lenses 19 backs or behind the 4th polarization splitting prism 22, can add condenser second, outgoing beam is compiled into the optical fiber port.

The specific design of present embodiment is as follows:

The aperture compound imaging resolution requirement 25mm of a synthetic aperture laser imaging radar, imaging viewing distance are 4,10,20km.Therefore the aperture diaphragm diameter on the telescope objective entrance pupil face is φ 50mm.

The enlargement factor that designs a telescope is M=10, and telescope objective 13 bores are that φ 60mm (＞φ 50mm) and focal length are 1000mm, and the bore of telescope ocular 12 is that φ 7mm (＞φ 5mm) and focal length are 100mm.First focal length that receives the image rotation lenses 17 and the second reception image rotation lenses 19 is 100mm.The focal length of the first emission image rotation lenses 6 and the second emission image rotation lenses 9 is 100mm.

Receiving telescope should be controlled telescopical equivalent defocus amount for the quadratic term aberration of eliminating incident wavefront, be equivalent to receive the telescopical defocusing amount of image rotation and be 0.25,0.1,0.05mm, in received signal, produce phase place quadratic term course in the time of out of focus, be equivalent to curvature and be 4,10,20km.

4,10, the Gaussian beam wavefront curvature at 20km place is 4,10,20km, consider the quadratic term phase history that echo receives, the curvature of total equivalent wavefront is 2,5,10km, the wave height number that is equivalent to the half-wave on the illumination radius is 1.786,4.47,8.93, can require half-wave wave height number for the ease of correct sampling and inverting is 20, at this moment need that equivalent curvature of additional biasing is 0.196,1.437, the quadratic term of 8.068km, the quadratic term equivalent focal length that promptly receives space phase modulation dull and stereotyped 15 should be 0.049,0.05748,0.0807mm.

Claims (4)

1, a kind of bidirectional loop transmitting-receiving telescope for synthesis of synthetic aperture laser imaging radar, it is characterized in that: the LASER Light Source (1) that comprises synthetic aperture laser imaging radar, along this LASER Light Source (1) emission laser beam is first half-wave plate (2) and first polarization splitting prism (3) successively, described laser beam is divided into reflection and transmitted light beam by first polarization splitting prism (3), this first polarization splitting prism (3) folded light beam is as the local oscillation laser beam, this local oscillation laser beam returns back arrival and enters the 3rd polarization splitting prism (20) by this first polarization splitting prism (3) output through first quarter-wave plate (4) and by first catoptron (5), this first polarization splitting prism (3) transmitted light beam is as the emission laser beam, this emission laser beam is successively through the first emission image rotation lenses (6), emission defocusing amount (7), emission space phase modulation (PM) plate (8), the second emission image rotation lenses (9), second polarization splitting prism (10), second quarter-wave plate (11), telescope ocular (12), telescope objective (13) and telescope go out entrance pupil (14) directive target, the echo laser beam of this target returns through former road, go out entrance pupil (14) through telescope, telescope objective (13), telescope ocular (12), second quarter-wave plate (11) is to described second polarization splitting prism (10), through again after the reflection and reception space phase modulation panel (15), second catoptron (16), first receives image rotation lenses (17), receive defocusing amount (18), second receives image rotation lenses (19) arrives the 3rd polarization splitting prism (20), described echo laser beam and described local oscillation laser beam close bundle by the 3rd polarization splitting prism (20), again through second half-wave plate (21) and by the 4th polarization splitting prism (22) polarization spectro, the synthetic light beam that all is the horizontal direction polarization carries out heterodyne reception by first photodetector (23), all is that the synthetic light beam of vertical direction polarization carries out heterodyne reception by second photodetector (24);

All polarization splitting prisms are set at the horizontal polarization direction light beam to be passed through and the vertical polarization beam reflection;

The angle of described first quarter-wave plate (4) is arranged so that the local oscillation laser beam that reflects from first polarization splitting prism (3) turns back to polarization on first polarization splitting prism (3) from first catoptron (5) and rotated 90 ° and can directly pass through this first polarization splitting prism (3);

The angle of described second quarter-wave plate (11) is arranged so that the emission laser beam that sees through second polarization splitting prism (10) through the telescope emission, and the echo of target reflection also turns back to polarization on second polarization splitting prism (10) by the light beam that telescope receives and rotated 90 ° and can be reflected by second polarization splitting prism (10);

Described telescope objective (13) and telescope ocular (12) are formed the antenna telescope that is used for Laser emission and reception, and the focal length of this telescope objective (13) is f ₁And the focal length of telescope ocular (12) is f ₂, the distance between the front focal plane of the back focal plane of telescope ocular (12) and telescope objective (13) is telescopical defocusing amount: $\mathrm{\&Delta;l}=-\frac{f_1^2}{z+R},$ In the formula: z is the synthetic aperture laser imaging radar range-to-go, and R is the radius-of-curvature of emission beam wave surface on distance Z;

Telescopically go out entrance pupil (14) and be positioned on the outer focal plane of telescope objective (13), the outer focal plane of described telescopical eyepiece (12) is the telescopical emergent pupil face of going into, and describedly telescopically goes out entrance pupil face (14) and goes into the emergent pupil face and be in picture with telescopical;

The described first emission image rotation lenses (6) and the second emission image rotation lenses (9) are formed an emission 4-f image rotation telescope, emergent pupil plane and the antenna of the second emission image rotation lenses (9) be telescopical goes into the emergent pupil face and overlaps, described emission space position phase modulation panel (8) is placed on the front focal plane of the second emission image rotation lenses (9), and the focal length of the first emission image rotation lenses (6) and the second emission image rotation lenses (9) is f ₃, the defocusing amount (7) of focal plane was in the middle of described emission 4-f image rotation was telescopical:

${\mathrm{\&Delta;l}}_3=-\frac{f_1^2{f}_3^2}{(Z+R)f_2^2},$

In the formula: z is the synthetic aperture laser imaging radar range-to-go, and the space phase quadratic term equivalent focal length of this emission space position phase modulation panel (8) is:

$R_3=\frac{f_3^2}{f_2^2}F,$ F is the equivalent focal length of space bit phase quadratic term biasing in the formula, $F=\frac{f_1^2}{2z};$

Described first receives image rotation lenses (17) and second receives a reception of image rotation lenses (19) composition 4-f image rotation telescope, the first entrance pupil face that receives image rotation lenses (17) and antenna be telescopical goes into the emergent pupil face and overlaps, described reception space bit phase modulation panel (15) is placed on the telescopical entrance pupil face of this reception 4-f image rotation, and first focal length that receives the image rotation lenses (17) and the second reception image rotation lenses (19) is f ₄, the phase function of described reception space phase modulation panel (15) is:

In the formula: x, y are for receiving the position coordinates of space phase modulation panel (15), and λ is an optical maser wavelength; Focal plane out of focus in the middle of the perhaps described reception 4-f image rotation telescope, defocusing amount (18) is:

${\mathrm{\&Delta;l}}_4=\frac{f_1^2{f}_4^2}{z{f}_2^2}.$

2, a kind of bidirectional loop transmitting-receiving telescope for synthesis of synthetic aperture laser imaging radar, it is characterized in that: the LASER Light Source (1) that comprises synthetic aperture laser imaging radar, along this LASER Light Source (1) emission laser beam is first half-wave plate (2) and first polarization splitting prism (3) successively, described laser beam is divided into reflection and transmitted light beam by first polarization splitting prism (3), this first polarization splitting prism (3) folded light beam is as the local oscillation laser beam, this local oscillation laser beam returns back arrival and enters the 3rd polarization splitting prism (20) by this first polarization splitting prism (3) output through first quarter-wave plate (4) and by first catoptron (5), this first polarization splitting prism (3) transmitted light beam is as the emission laser beam, this emission laser beam is successively through the first emission image rotation lenses (6), emission defocusing amount (7), emission space phase modulation (PM) plate (8), the second emission image rotation lenses (9), second polarization splitting prism (10), second quarter-wave plate (11), telescope ocular (12), telescope objective (13) and telescope go out entrance pupil (14) directive target, the echo laser beam of this target returns through former road, go out entrance pupil (14) through telescope, telescope objective (13), telescope ocular (12), second quarter-wave plate (11) is to described second polarization splitting prism (10), through again after the reflection and reception space phase modulation panel (15), second catoptron (16), first receives image rotation lenses (17), receive defocusing amount (18), second receives image rotation lenses (19) arrives the 3rd polarization splitting prism (20), described echo laser beam and described local oscillation laser beam close bundle by the 3rd polarization splitting prism (20), again through second half-wave plate (21) and by the 4th polarization splitting prism (22) polarization spectro, the synthetic light beam that all is the horizontal direction polarization carries out heterodyne reception by first photodetector (23), all is that the synthetic light beam of vertical direction polarization carries out heterodyne reception by second photodetector (24);

All polarization splitting prisms are set at the horizontal polarization direction light beam to be passed through and the vertical polarization beam reflection;

The angle of described first quarter-wave plate (4) is arranged so that the local oscillation laser beam that reflects from first polarization splitting prism (3) turns back to polarization on first polarization splitting prism (3) from first catoptron (5) and rotated 90 ° and can directly pass through this first polarization splitting prism (3);

The angle of described second quarter-wave plate (11) is arranged so that the emission laser beam that sees through second polarization splitting prism (10) through the telescope emission, and the echo of target reflection also turns back to polarization on second polarization splitting prism (10) by the light beam that telescope receives and rotated 90 ° and can be reflected by second polarization splitting prism (10);

Described telescope objective (13) and telescope ocular (12) are formed the antenna telescope that is used for Laser emission and reception, and the focal length of this telescope objective (13) is f ₁And the focal length of telescope ocular (12) is f ₂, the distance between the front focal plane of the back focal plane of telescope ocular (12) and telescope objective (13) is telescopical defocusing amount Δ l=0; Describedly telescopically go out entrance pupil (14) and be positioned on the outer focal plane of telescope objective (13), the outer focal plane of described telescopical eyepiece (12) is the telescopical emergent pupil face of going into, and describedly telescopically goes out entrance pupil face (14) and goes into the emergent pupil face and be in picture with telescopical;

The described first emission image rotation lenses (6) and the second emission image rotation lenses (9) are formed an emission 4-f image rotation telescope, emergent pupil plane and the antenna of the second emission image rotation lenses (9) be telescopical goes into the emergent pupil face and overlaps, described emission space position phase modulation panel (8) is placed on the front focal plane of the second emission image rotation lenses (9), and the focal length of the first emission image rotation lenses (6) and the second emission image rotation lenses (9) is f ₃, the defocusing amount (7) of focal plane was in the middle of described emission 4-f image rotation was telescopical:

${\mathrm{\&Delta;l}}_3=-\frac{f_1^2+f_3^2}{(Z+R)f_2^2},$

In the formula: z is the synthetic aperture laser imaging radar range-to-go, and the equivalent focal length of the space phase quadratic term biasing of the phase modulation function of this emission space position phase modulation panel (8) generation is:

$F=\frac{f_2^2}{Z^2}R,$

In the formula: z is the synthetic aperture laser imaging radar range-to-go, and R is the radius-of-curvature of emission beam wave surface on distance Z;

Described first receives image rotation lenses (17) and second receives a reception of image rotation lenses (19) composition 4-f image rotation telescope, the first entrance pupil face that receives image rotation lenses (17) and antenna be telescopical goes into the emergent pupil face and overlaps, described reception space bit phase modulation panel (15) is placed on the telescopical entrance pupil face of this reception 4-f image rotation, and first focal length that receives the image rotation lenses (17) and the second reception image rotation lenses (19) is f ₄, the phase function of described reception space phase modulation panel (15) is:

In the formula: x, y are for receiving the position coordinates of space phase modulation panel (15), and λ is an optical maser wavelength; Focal plane out of focus in the middle of the perhaps described reception 4-f image rotation telescope, defocusing amount (18) is:

$\mathrm{\&Delta;}{l}_4=\frac{f_1^2{f}_4^2}{z{f}_2^2}.$

3, bidirectional loop transmitting-receiving telescope for synthesis according to claim 1 and 2 is characterized in that: described first half-wave plate (2) and second half-wave plate (21) can be used quarter-wave plate instead.

4, bidirectional loop transmitting-receiving telescope for synthesis according to claim 1 and 2 is characterized in that: describedly telescopically go out entrance pupil (14) and be positioned on the outer focal plane of telescope objective (13), be the aperture diaphragm of a reality, or only represent a position.

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