The present invention relates to a catadioptric optical system, and more particularly to a catadioptric telescope system for satellite remote-sensing images.
Satellite remote-sensing images can demonstrate an overview of a large-range land profile to help learn various topographies, such as mountains, plains, basins, coastlines, cities, rivers and roads, etc. Besides, disaster regions, for example landslide/landslip areas, mudslide areas, wildfire areas, etc. can be quickly identified and plotted in the image maps by virtue of comparison and analysis of the satellite remote-sensing images captured before and after natural or human disasters. The satellite remote-sensing images not only help people master the situation in time, but also provides accurate information to help find out reasons arising the disasters. The optical remote-sensing carrier of an artificial satellite is primarily composed of three subsystems including a remote-sensing instrument (RSI), a focal plane array (FPA) and an electronic unit (EU). The RSI is a large space-grade telescope. The catadioptric Cassegrain telescope is employed for a classical telescope, while the modern different telescope mostly utilizes the reflecting Ritchey-Chrétien telescope to alleviate off-axis aberration. The sun light reflected from the earth enters the optical remote-sensing payload located on the assignment of space orbit, then in sequence reflected by a primary mirror and a secondary mirror, then passing a corrector lens group and then focusing on an image sensing device of the FPA to transform to digital electronic signals.
A typical image sensing device is equipped with a micro-lens on each pixel to increase luminous flux received by its imaging surface in order that the pixel can become an effective pixel area. The micro-lens elements are easily affected and deformed by radiation and extreme variations of temperature in space environment, and even deteriorate image quality of the image sensing device. So, the image sensing device of the optical RSI has not a micro-lens on each pixel. As the incident angle of light increases, the luminous flux of the incident light received by the effective pixel area is diminished. As a consequence, the brightness contrast between the central area and the off-axis area of the pixel is decreased to unfavorably influence the image quality of the image sensing device. Once the images outputted from the image sensing device is required to be stitched to form a whole image, dark stripes would appear on the whole image.
The present invention provides a catadioptric optical system which can be served as a catadioptric telescope, particularly as a Ritchey-Chrétien type telescope. Incident light passing through the present catadioptric optical system becomes corrected beams having small CRAs (Chief Ray Angles). When the corrected beams having small CRAs project onto an image sensing device, each pixel area of the image sensing device receives uniform luminous flux, and hence the relative illumination of an image quality from the image sensing device is increased.
In various implements, the present invention provides a catadioptric optical system, comprising in sequence of ray tracing: a first mirrors group of Ritchey-Chrétien type hyperbolic mirrors with positive diopter including a concave primary mirror having a central through hole and a convex secondary mirror; and a second corrector lens group with negative diopter positioned at an image side of the first mirrors group and from the image side of the first mirrors group in order including a first meniscus lens element having positive refractive power and a convex object-side surface, a second lens element with negative refractive power having a concave object-side surface and a concave image-side surface, a third meniscus lens element having negative refractive power and a concave object-side surface, and a fourth lens element with positive refractive power having a convex object-side surface and a convex image-side surface; wherein a diopter of the whole catadioptric optical system is DW, a diopter of the second corrector lens group is DL, and the following condition is satisfied:
wherein,
P0=−4.95*10−1,
P1=−1.81*10−3,
P2=5.59*10−7,
P3=−7.76*10−11,
P4=4.4*10−15,
EFL is an effective focal length of the present catadioptric optical system, and (±10%) means a tolerance allowance range of the present catadioptric optical system under an actual measure.
According to various implements of the present invention, the first lens element is constituted of a singular lens element and has an image-side surface being concave.
According to various implements of the present invention, the third lens element is constituted of a singular lens element and has an image-side surface being convex.
According to various implements of the present invention, a diopter of the first lens element is DL1, a diopter of the second lens element is DL2, a diopter of the third lens element is DL3, a diopter of the fourth lens element is DL4, and the following conditions are satisfied:
wherein,
wherein,
wherein,
wherein,
N0=−5.99,
N1=−1.52*10−3,
N2=1*10−6,
N3=−1.95*10−10,
N4=1.11*10−14,
EFL is an effective focal length of the present catadioptric optical system, and (±10%) means a tolerance allowance range of the present catadioptric optical system under an actual measure.
According to various implements of the present invention, a composite diopter of the first lens element and the second lens element is DL12, a composite diopter of the second lens element and the third lens element is DL23, and a composite diopter of the third lens element and the fourth lens element is DL34, and the following conditions are satisfied:
wherein,
wherein,
wherein,
T0=−4.23,
T1=1.66*10−4,
T2=1.16*10−7,
T3=−3.25*10−11,
T4=1.2*10−15,
EFL is an effective focal length of the present catadioptric optical system, and (±10%) means a tolerance allowance range of the present catadioptric optical system under an actual measure.
According to various implements of the present invention, the first lens element, the second lens element, the third lens element and the fourth lens element are made of the same optical material.
According to various implements of the present invention, the first lens element, the second lens element, the third lens element and the fourth lens element are made of glass material, a refractive index of the glass material is nd, an Abbe number of the glass material is y d, and the following conditions are satisfied:
1.44<nd<1.47; and
64.41<νd<71.19.
According to various implements of the present invention, the present catadioptric optical system further comprises a third reflective surfaces group and a fourth image sensing group, wherein the third reflective surfaces group is positioned at an image side of the second corrector lens group and includes a first reflective surface and a second reflective surface, a contained angle is between the first reflective surface and the second reflective surface, an apex of the contained angle is positioned at an optical axis of the catadioptric optical system and faces toward the second corrector lens group, the fourth image sensing group includes a first image sensing device and a second image sensing device respectively placed at an image side of the first reflective surface and an image side of the second reflective surface.
According to various implements of the present invention, a distance on the optical axis between the convex object-side surface of the first lens element facing toward the convex secondary mirror and the convex image-side surface of the fourth lens element facing toward the third reflective surfaces group is TLL1L4, and the following condition is satisfied:
TLL1L4=(U4EFL4+U3EFL3+U2EFL2+U1EFL+U0)*(1±10%);
According to various implements of the present invention, a chief ray angle of a corrected beam of the incident light corrected through the catadioptric optical system is CRA, and the following condition is satisfied:
CRA<3.5 degrees.
The present catadioptric optical system is a catadioptric telescope comprising Ritchey-Chrétien type primary and secondary hyperbolic mirrors, four elements corrector lens group and a reflective surfaces group. The infinite conjugate beams of incident light falling on the primary mirror, converging to the secondary mirror are reflected, then passing and being corrected through the corrector lens group to become corrected beams having small chief ray angles. The corrected beams having small chief ray angles are reflected by the reflective surfaces group and then focused unto image sensing devices, correspondingly.
The present catadioptric optical system will be described in detail according to the following embodiment accompanying with the appended drawings.
A third reflective surfaces group 30 is positioned at an image side of the second corrector lens group 20 and includes a first reflective surface 310 and a second reflective surface 320, a contained angle is between the first reflective surface 310 and the second reflective surface 320, an apex 300 of the contained angle is positioned at an optical axis OO′ of the catadioptric optical system and faces toward the second corrector lens group 20.
A fourth image sensing group includes a first image sensing device 40 and a second image sensing device 42 respectively placed at corresponding image surfaces of the present catadioptric optical system, which are located at an image side of the first reflective surface 310 and an image side of the second reflective surface 320. In various implements of the present invention, the first image sensing device 40 can be a linear image sensing device and the second image sensing device 42 can be an area-array image sensing device.
The optical data of five implements of the present catadioptric optical system of
In the implements of Table I through Table V, with the implement of Table I as an example for explanation: the numberings of “Surface” column correspond element numerals shown in the drawings, “Thickness” column represents an on-axis air (vacuum) gap between adjacent lens surfaces or a lens element thickness, for instance −375.99 mm means an air (vacuum) gap on the optical axis OO′ between the concave reflective mirror surface 111 and the convex reflective mirror surface 121, 418.30 mm means an air (vacuum) gap on the optical axis between the convex reflective surface 121 and the object-side surface 211 of the first lens element 210, 17.19 mm means a thickness of the first lens element 210, and so on. Besides, in the implement of Table I, a distance between the first reflective surface 310 and the corresponding image surface of the present catadioptric optical system is 41.05 mm, a distance between the second reflective surface 320 and the corresponding image surface of the present catadioptric optical system is also 41.05 mm; in the implement of Table II, a distance between the first reflective surface 310 and the corresponding image surface of the present catadioptric optical system is 67.04 mm, a distance between the second reflective surface 320 and the corresponding image surface of the present catadioptric optical system is also 67.04 mm; in the implement of Table III, a distance between the first reflective surface 310 and the corresponding image surface of the present catadioptric optical system is 116.51 mm, a distance between the second reflective surface 320 and the corresponding image surface of the present catadioptric optical system is also 116.51 mm; in the implement of Table IV, a distance between the first reflective surface 310 and the corresponding image surface of the present catadioptric optical system is 136.48 mm, a distance between the second reflective surface 320 and the corresponding image surface of the present catadioptric optical system is also 136.48 mm; in the implement of Table V, a distance between the first reflective surface 310 and the corresponding image surface of the present catadioptric optical system is 161.97 mm, a distance between the second reflective surface 320 and the corresponding image surface of the present catadioptric optical system is also 161.97 mm.
In the embodiment, a diopter of the catadioptric optical system is DW, a diopter of the second corrector lens group is DL, and the following condition is satisfied:
wherein,
P0=−4.95*10−1,
P1=−1.81*10−3,
P2=5.59*10−7,
P3=−7.76*10−11,
P4=4.4*10−15,
EFL is an effective focal length of the catadioptric optical system, and (±10%) means a tolerance allowance range of the present catadioptric optical system under an actual measure.
In the embodiment, a diopter of the first lens element is DL1, a diopter of the second lens element is DL2, a diopter of the third lens element is DL3, a diopter of the fourth lens element is DL4, and the following conditions are satisfied:
wherein,
wherein,
wherein,
wherein,
N0=−5.99,
N1=−1.52*10−3,
N2=1*10−6,
N3=−1.95*10−10,
N4=1.11*10−14,
EFL is an effective focal length of the catadioptric optical system, and (±10%) means a tolerance allowance range of the present catadioptric optical system under an actual measure.
In the embodiment, a composite diopter of the first lens element and the second lens element is DL12, a composite diopter of the second lens element and the third lens element is DL23, and a composite diopter of the third lens element and the fourth lens element is DL34, and the following conditions are satisfied: DL12
wherein,
wherein,
wherein,
T0=−4.23,
T1=1.66*10−4,
T2=1.16*10−7,
T3=−3.25*10−11,
T4=1.2*10−15,
EFL is an effective focal length of the catadioptric optical system, and (±10%) means a tolerance allowance range of the present catadioptric optical system under an actual measure.
Please refer to
Table VI shows a correlation between field of views vs. chief ray angles of the corrected beams of the present catadioptric optical systems in the implements corresponding to Table I through Table V.
It is to be noted that Table I through Table V show optical data of the different implements. However, the data of the different implements are obtained from experiments. The implements depicted above and the appended drawings are exemplary and are not intended to be exhaustive or to limit the scope of the present disclosure to the precise forms disclosed. Many modifications and variations are possible in view of the above teachings.
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