CN100449350C - Super thin reflective projection display imaging method and objective lens based on free camber - Google Patents
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Abstract
This invention discloses a kind of extra-thin reflection type projected display imaging method based on free curved surface and object lens. It has concave catopter, convex catopter, convex catopter, object plane and image surface in proper order. The merit of the invention are: 1) adopting free curved surface imaging method , three part reflection type Zernike polynomial free curved surface forms short focal distance bigger, relative apertures bigger fields of view angle imaging , rectifying optical aberration much better and its structure is simple; 2) adopting the reflection structure without optical lens, has removed the effect of various chromatic aberration , guarantee the imaging articulation; 3) adopt the design of short focal distance big fields of view angle, focal distance 8 - 15 mm, field of view angles 100 -135 degree, having 120 times multiplications under 250 mm imaging distance, having ultra-thin characteristic property; 4) adopting big relative apertures design ,the relative aperture is 2.0-2.4, having improved the illuminance of flat surface; 5) adopting image space telecentric imaging method , ensures that the image surface irradiance is homogeneous.
Description
Technical field
The present invention relates to a kind of super thin reflective projection display imaging method and object lens based on free form surface.
Background technology
Projection display technique develops rapidly in recent years, giant-screen, high-definition image show it is the major advantage of Projection Display, and its volume is little, in light weight, can be widely used in aspects such as electronic teaching, office, commercial affairs and advertisement recreational, and application prospect is very extensive.Difference according to the display device of using, the projection display technique of using has DMD, LCD, LCoS Projection Display at present, Projection Display forms image source with digital signal or other vision signals that computing machine produces through driving circuit on display device, the light that light source is sent by illuminator by the display device modulation after, on screen, form coloured image by projection imaging object lens amplification imaging again.
In projection display system, the projection imaging object lens have important effect, many performances of system especially sharpness etc. are closely related with the projection imaging object lens, optical projection system requires to shorten as much as possible projector distance at present simultaneously, with can be under the short distance situation projection large tracts of land, and in projection display system, because the job requirement of illuminated object (image device) and system, telecentric light need be provided, and the relative aperture of the corresponding increase image-forming objective lens of needs is to improve the output brightness of system, therefore, in the optical projection system for efficient high brightness, projection objective is short Jiao, big relative opening, the telecentric imaging object lens of big field angle.Therefore the overall development trend of image-forming objective lens is short focal length, big field angle, object lens of large relative aperture and high definition, this has just formed the design of image-forming objective lens and the difficulty of production is improving constantly, the transmission-type image-forming objective lens that generally adopts is owing to the increase along with field angle and relative aperture at present, can cause various aberration, off-axis aberration, the rapid variation of distortion also is difficult to be proofreaied and correct simultaneously, with regard to needs new image-forming objective lens version is proposed constantly for satisfying performance requirement, or the version of image-forming objective lens is carried out complicated, so the image-forming objective lens structure of transmission-type can become increasingly complex and exist certain limitation.And the design concept of reflective image-forming objective lens more and more has been much accounted of, present reflective image-forming objective lens adopts the aspheric structure of even to design mostly, the even aspheric surface is the rotation symmetry, and adopt the aspheric image-forming objective lens of even under the situation of very short projector distance, will cause the increase of field angle, cause the increase of various aberration, simultaneously under the situation of the big visual field of short focal length, aberration still is difficult to obtain simultaneously correct, be difficult to guarantee imaging definition, and aspheric surface is under the bigger situation of face shape, all there is certain difficulty aspect processing and the surface shape measurement, along with the at full speed progress of processing in recent years with detection technique, free form surface development rapidly, the aspheric surface of the even axial symmery shape that free form surface is more traditional has bigger design freedom, thereby spherical aberration corrector better, various aberrations such as coma, obtain better image quality, and make simplified structure, reducing cost becomes possibility.
Summary of the invention
The purpose of this invention is to provide a kind of super thin reflective projection display imaging method and object lens based on free form surface.
Super thin reflective projection display imaging method based on free form surface comprises:
1) be used to proofread and correct spherical aberration that reflection produces from axle and coma recessed reflecting surface S1, be used to proofread and correct the off-axis aberration that causes by object lens of large relative aperture with from axle protruding reflecting surface S2, be used to proofread and correct the reflective structure of the protruding reflecting surface S3 of the distortion that produces from axle, recessed reflecting surface S1, protruding reflecting surface S2, protruding reflecting surface S3 utilize Zernike polynomial free curved surface aberration correction;
2) adopt repeatedly folding reflection to cooperate and prolong distance between each reflecting surface, utilize the distance that prolongs between the reflecting surface to shorten whole projection imaging distance from the axle mode;
3) adopt the reflective imaging of the big field angle of short focal length object lens of large relative aperture that improves as the illuminance on the plane, focal length is 8~15mm, and relative aperture is 2.0~2.4, and field angle is 100~135 degree;
4) adopt the uniform telecentric beam path in image space structure of assurance image planes irradiance.
Based on the super thin reflective projection display imaging object lens of free form surface have successively being used to of placing in opposite directions proofread and correct spherical aberration that reflection produces from axle and coma recessed reflecting surface S1, be used to proofread and correct the various off-axis aberration that cause by object lens of large relative aperture with from axle protruding reflecting surface S2, be used to proofread and correct the protruding reflecting surface S3 of the distortion that produces from axle, protruding reflecting surface S2 placement location is higher than recessed reflecting surface S1, and protruding reflecting surface S3 placement location is higher than protruding reflecting surface S2.
Advantage of the present invention is:
1) adopt the free form surface formation method, three reflective Zernike polynomial free curved surface form the big field angle imaging of short focal length object lens of large relative aperture, and aberration correction is simple in structure better;
2) reflective structure of the no form of lens of employing has been eliminated various aberration influences, guarantees imaging definition;
3) adopt the big field angle design of short focal length, focal length 8~15mm has the field angle of 100~135 degree, and 120 times enlargement factor is arranged under the 250mm image-forming range, has ultra-thin characteristic;
4) adopt the object lens of large relative aperture design, relative aperture is 2.0~2.4, improves as the illuminance on the plane;
5) adopt as square telecentric imaging method, guarantee that the image planes irradiance is even.
Description of drawings
Fig. 1 is based on the super thin reflective projection display imaging structural representation of free form surface;
Fig. 2 is a detailed structure synoptic diagram of the present invention;
Fig. 3 is an imaging modulation transfer function of the present invention;
Fig. 4 (a) is the point range figure of 1 position, image planes top after the normalization of the present invention;
Fig. 4 (b) is the point range figure of 0.5 position, image planes top after the normalization of the present invention;
Fig. 4 (c) is the point range figure of image planes center position after the normalization of the present invention;
Fig. 4 (d) is the point range figure of 0.5 position, image planes below after the normalization of the present invention;
Fig. 4 (e) is the point range figure of 1 position, image planes below after the normalization of the present invention;
Fig. 5 (a) is the pupil surface aberration figure of 1 position, image planes top after the normalization of the present invention;
Fig. 5 (b) is the pupil surface aberration figure of 0.5 position, image planes top after the normalization of the present invention;
Fig. 5 (c) is the pupil surface aberration figure of image planes center position after the normalization of the present invention;
Fig. 5 (d) is the pupil surface aberration figure of 0.5 position, image planes below after the normalization of the present invention;
Fig. 5 (e) is the pupil surface aberration figure of 1 position, image planes below after the normalization of the present invention;
Fig. 6 (a) is the curvature of field curve of image-forming objective lens of the present invention;
Fig. 6 (b) is the distortion curve of image-forming objective lens of the present invention.
Fig. 7 is the distortion shape synoptic diagram of image-forming objective lens of the present invention.
Embodiment
Super thin reflective projection display imaging method based on free form surface comprises:
1) be used to proofread and correct spherical aberration that reflection produces from axle and coma recessed reflecting surface S1, be used to proofread and correct the off-axis aberration that causes by object lens of large relative aperture with from axle protruding reflecting surface S2, be used to proofread and correct the reflective structure of the protruding reflecting surface S3 of the distortion that produces from axle, recessed reflecting surface S1, protruding reflecting surface S2, protruding reflecting surface S3 utilize Zernike polynomial free curved surface aberration correction;
2) adopt repeatedly folding reflection to cooperate and prolong distance between each reflecting surface, utilize the distance that prolongs between the reflecting surface to shorten whole projection imaging distance from the axle mode;
3) adopt the reflective imaging of the big field angle of short focal length object lens of large relative aperture that improves as the illuminance on the plane, focal length is 8~15mm, and relative aperture is 2.0~2.4, and field angle is 100~135 degree;
4) adopt the uniform telecentric beam path in image space structure of assurance image planes irradiance.
As shown in Figure 1, it have successively in opposite directions being used to of placing proofread and correct spherical aberration that reflection produces from axle and coma recessed reflecting surface S1, be used to proofread and correct the various off-axis aberration that cause by object lens of large relative aperture with from axle protruding reflecting surface S2, be used to proofread and correct the protruding reflecting surface S3 of the distortion that produces from axle, protruding reflecting surface S2 placement location is higher than recessed reflecting surface S1, and protruding reflecting surface S3 placement location is higher than protruding reflecting surface S2.
Image-forming objective lens be three reflective from axle construction, three recessed reflecting surface S1, protruding reflecting surface S2, protruding reflecting surface S3 adopt Zernike free form surface reflecting surface respectively, and be from the axle working method, the focal length forms of distribution just are being followed successively by-are bearing-bear form, be recessed reflecting surface S1 focal length for just, protruding reflecting surface S2, protruding reflecting surface S3 focal length are for negative.Adopt repeatedly folding reflection to cooperate in the design and prolong distance between each reflecting surface from the axle mode, the light that is sent by display device S4 is after recessed reflecting surface S1 reflection, folding returning reaches the protruding S2 of reflecting surface, protruding reflecting surface S2 is a little more than being distal to display device S4, the protruding S3 of reflecting surface is returned in folding once more reflection behind the protruding S2 of reflecting surface, protruding reflecting surface S3 is higher than again and is distal to the protruding S2 of reflecting surface, protruding through behind the reflecting surface S3 again secondary reflection return and reach on the screen S 5, thereby reach the effect of shortening projection distance by folding reflection repeatedly; And reflective structure can have been eliminated the influence of material refractive index, color difference eliminating fully; And recessed reflecting surface S1, protruding reflecting surface S2, protruding reflecting surface S3 adopt Zernike polynomial free curved surface reflecting surface respectively, and the Zernike polynomial free curved surface has the more freedom degree, can reduce aberration the biglyyest, thereby promote clearness.
Recessed reflecting surface S1, protruding reflecting surface S2, protruding reflecting surface S3 all adopt the reflective free form surface version of Zernike polynomial expression, and the version of free form surface can be described by the Zernike polynomial expression, represent suc as formula (1):
In the formula (1), r
2=x
2+ y
2, (x, y): the Sag amount, k: the circular cone coefficient, c: the curvature of basic sphere, A are located in the curved surface summit to Z
i: multinomial coefficient, E
i(x, y): be polynomial expression.
The polynomial expression item is launched, can be written as:
The polynomial expression item number is:
By formula (2) as can be seen, even aspheric surface with traditional rotation symmetric form is compared, the Zernike polynomial free curved surface is a unsymmetric form, thereby has a more design freedom, at various aberrations such as spherical aberration corrector, coma, distortion better in the imaging shaft system, obtain better image quality.
The Zernike polynomial free curved surface of formula (1) can be write as polar form, that is:
In the formula (3), B
iBe the multinomial coefficient under the polar form, ρ is the length of the pole axis under the polar coordinates, and θ is the angle of the pole axis under the polar coordinates.
Zernike polynomial expression under the polar coordinates situation is every to be linear independence each other, to being used for describing the wavefront border of optical system after its normalization, therefore, sets up certain corresponding relation with the Seidel aberration of object lens:
With the Zernike polynomial expression every with Seidel aberration item set up corresponding after, each aberration coefficients of individual processing selectively, thus proofread and correct aberrations at different levels respectively.
Fig. 2 is an image-forming objective lens detailed structure synoptic diagram, reflecting surface S1 adopts the concave mirror form, focal length be on the occasion of, be mainly used in and proofread and correct spherical aberration and the coma that reflection produces from axle, and adopt the concave mirror structure can guarantee to assemble through reflecting surface S1 by the light of display device face, thereby reduce follow-up aperture of a mirror, move after making the total system interarea simultaneously, reach the long back work distance requirement of system, and reflecting surface S1 bending is to the display device direction, and the big off-axis ray of field angle is after reflecting surface S1 assembles, and field angle diminishes with respect to back mirror, thereby reach the purpose that enlarges field angle, the focal length of reflecting surface S1 meets the following conditions:
3.5<F1/F<4.0 (4)
Wherein, F1 is the focal length of reflecting surface S1, and F is the whole focal length of system.
Formula (4) is the focal length distributive condition of reflecting surface S1, the condition that formula (4) must satisfy for the structure aberration balancing, when F1/F<3.5, one-piece construction just is difficult to proofread and correct caused aberration under the big field angle condition of object lens of large relative aperture, when F1/F>4.0, will cause big spherical aberration and coma, strengthen the imaging pressure of follow-up reflecting surface, make aberration be difficult to correct.Simultaneously, reflecting surface S1 also serves as focal length inching function, by moving of reflecting surface S1 displacement, remains unchanged to guarantee imaging process image planes position.
Reflecting surface S2 is the convex mirror of free form surface form, is mainly used in correction by object lens of large relative aperture and the various off-axis aberration that cause from axle, and focal length is assigned as negative, is used to proofread and correct off-axis aberration such as the coma and the curvature of field, and the focal length of reflecting surface S2 distributes and satisfies:
-5.0<F2/F<-4.5(5)
Wherein, F2 is the focal length of back reflection face S2, and F is the whole focal length of system.
Formula (5) is the focal length distributive condition of reflecting surface S1, the condition that formula (5) must satisfy for the structure aberration balancing, when F2/F<-5.0, one-piece construction just is difficult to proofread and correct the caused coma of zoom under the object lens of large relative aperture condition, when F5/F>-4.5, the back work distance that will shorten system from, the system rear cut-off distance of causing is not enough to satisfy condition.
Reflecting surface S3 is the convex mirror of free form surface form also, is mainly used in the distortion that correction produces from axle, and focal length is assigned as negative, and the focal length of reflecting surface S3 distributes satisfied:
-10.0<F3/F<-9.0(6)
Reflecting surface S3 can adopt around the bottom of reflecting surface and rotate, and can proofread and correct better like this because the distortion that screen inclination produces.
Image-forming objective lens is whole to be adopted as square telecentric imaging method design, can guarantee that the light that is sent by display device enters object lens as much as possible, thereby guarantee the illumination and the illuminance uniformity of image planes.
Table 1 is the detail parameters of each reflective free form surface:
Table 1: catoptric imaging objective lens arrangement detail parameters
In the parameter of each reflecting curved surface basic parameter table 1 of table 1, formula (1) is seen in the definition of radius-of-curvature C and circular cone COEFFICIENT K, and the position is that the center with display device is a true origin, and horizontal orientating reflex face S1 direction is a directions X.
Table 2 is the every multinomial coefficient of each reflecting curved surface Zernike polynomial expression
The every coefficient detail parameters of table 2:Zernike polynomial expression
Item number | Polynomial expression Ei (x, y) | Reflecting surface S1 Ai | Reflecting surface S2 Ai | Reflecting |
1 | |
0 | 0 | 0 |
2 | X0Y1 | -0.2795 | -0.085219195 | -0.51823812 |
3 | X2Y0 | -0.000127172 | -0.000189189 | 0.000980361 |
4 | |
0 | 0 | 0 |
5 | X0Y2 | -0.000294935 | 0.000605635 | 0.002832199 |
6 | |
0 | 0 | 0 |
7 | X2Y1 | -9.04E-06 | -2.98E-05 | -1.14E-05 |
8 | |
0 | 0 | 0 |
9 | X0Y3 | -9.76E-06 | -2.81E-05 | -1.70E-05 |
10 | X4Y0 | 5.25E-08 | 1.11E-09 | -9.84E-08 |
11 | |
0 | 0 | 0 |
12 | X2Y2 | 1.17E-07 | -1.75E-07 | -1.33E-07 |
13 | |
0 | 0 | 0 |
14 | X0Y4 | 3.74E-08 | 4.07E-07 | -6.76E-08 |
15 | |
0 | 0 | 0 |
16 | X4Y1 | -1.09E-09 | -3.38E-08 | 2.81E-09 |
17 | |
0 | 0 | 0 |
18 | X2Y3 | -1.23E-09 | -5.89E-08 | 1.46E-09 |
19 | |
0 | 0 | 0 |
20 | X0Y5 | -7.08E-10 | -5.01E-08 | 1.10E-09 |
21 | X6Y0 | 1.77E-12 | 1.77E-10 | 1.45E-12 |
22 | |
0 | 0 | 0 |
23 | X4Y2 | -1.20E-11 | 2.48E-09 | -1.73E-11 |
24 | |
0 | 0 | 0 |
25 | X2Y4 | -6.33E-12 | 2.36E-09 | 1.70E-11 |
26 | |
0 | 0 | 0 |
27 | X0Y6 | -2.31E-12 | 1.19E-09 | -2.82E-13 |
28 | |
0 | 0 | 0 |
29 | |
0 | 0 | -2.4386463e-013 |
Wherein, (x is every in the formula (2) y) to polynomial expression item Ei, parameters in the Ai formula (2).
Fig. 3 is the modulation transfer function of image-forming objective lens of the present invention; Can reach 60 lines to more than 60% in image planes, and meridian separates with the sagitta of arc for a short time, the modulation transfer function at center is near diffraction limit, thereby tolerances in design is big, is easy to guarantee processing.
Fig. 4 is the point range figure of the present invention in each position of image planes, the top numeral is the object plane position among each figure of Fig. 4, transfer numeral and be corresponding image planes position, as with after its normalization, then be respectively the point range figure of normalization image planes top 1, image planes top 0.5, center, 0.5 position, image planes below, 1 position, image planes below; Can from each figure of Fig. 4, find out, because from axle, the point range figure size of image planes below is greater than the point range figure of image planes top, thereby the sharpness of image planes top will be higher than the sharpness of image planes top.
Fig. 5 is the pupil surface aberration figure of the present invention in each position of image planes, the top numeral is the object plane position among each figure of Fig. 5, as with after its normalization, then be respectively the point range figure of normalization image planes top 1, image planes top 0.5, center, 0.5 position, image planes below, 1 position, image planes below; Left side figure is the pupil surface aberration of sub-object plane among each figure, and right figure is the pupil surface aberration of sagittal surface, can find out that from each figure of Fig. 5 the sagittal surface aberration is less than the meridian ellipse aberration, and the sagittal surface aberration of image planes top is less than the sagittal surface aberration of image planes below.
Fig. 6 (a) is the curvature of field curve of image-forming objective lens of the present invention; Fig. 6 (b) is the distortion curve of image-forming objective lens of the present invention.Fig. 6 (b) shows that the distortion of image-forming objective lens of the present invention can be satisfied the image quality requirement fully less than 2%.Fig. 7 is the distortion shape synoptic diagram of image-forming objective lens of the present invention.Solid line partly is desirable position, and the position, point of crossing is the distortion figure signal of the real system of simulation.
Claims (1)
1. super thin reflective projection display imaging method based on free form surface is characterized in that comprising:
1) is used to proofread and correct reflection from the spherical aberration of axle generation and the recessed reflecting surface S1 of coma, be used to proofread and correct the protruding reflecting surface S2 of the off-axis aberration that causes by object lens of large relative aperture with from axle, be used to proofread and correct the reflective structure of the protruding reflecting surface S3 of the distortion that produces from axle, recessed reflecting surface S1, protruding reflecting surface S2, protruding reflecting surface S3 utilizes Zernike polynomial free curved surface aberration correction, recessed reflecting surface S1 adopts Zernike polynomial free curved surface structure, focal length be on the occasion of, the focal length of recessed reflecting surface S1 meets the following conditions: 3.5<F1/F<4.0, wherein, F1 is the focal length of recessed reflecting surface S1, F is the whole focal length of the image-forming objective lens of three free form surfaces formations, protruding reflecting surface S2 adopts Zernike polynomial free curved surface structure, focal length is a negative value, the focal length of protruding reflecting surface S2 meets the following conditions :-5.0<F2/F<-4.5, wherein, F2 is the focal length of protruding reflecting surface S2, protruding reflecting surface S3 adopts Zernike polynomial free curved surface structure, focal length is a negative value, the focal length of protruding reflecting surface S3 meets the following conditions :-10.0<F3/F<-9.0, wherein, F3 is the focal length of protruding reflecting surface S3; Protruding reflecting surface S2 placement location is higher than recessed reflecting surface S1, and protruding reflecting surface S3 placement location is higher than protruding reflecting surface S2, and recessed reflecting surface S1, protruding reflecting surface S2, protruding reflecting surface S3 place successively in opposite directions;
2) adopt repeatedly folding reflection to cooperate and prolong distance between each reflecting surface, utilize the distance that prolongs between the reflecting surface to shorten whole projection imaging distance from the axle mode;
3) adopt the reflective imaging of the big field angle of short focal length object lens of large relative aperture that improves as the illuminance on the plane, focal length is 8~15mm, and relative aperture is 2.0~2.4, and field angle is 100~135 degree;
4) adopt the uniform telecentric beam path in image space structure of assurance image planes irradiance.
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US20020191161A1 (en) * | 2001-03-29 | 2002-12-19 | Fuji Photo Optical Co., Ltd. | Reflection type projection optical system |
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US20040156117A1 (en) * | 2003-02-06 | 2004-08-12 | Atsushi Takaura | Projection optical system, magnification projection optical system, magnification projection apparatus, and image projection apparatus |
CN1432837A (en) * | 2003-02-28 | 2003-07-30 | 清华大学 | Astigmatism eliminating three spherical reflector system |
CN1769953A (en) * | 2004-11-01 | 2006-05-10 | 株式会社日立制作所 | Projection image display apparatus and projection optical unit to be used therein |
US20060152822A1 (en) * | 2004-11-25 | 2006-07-13 | Masayuki Imaoka | Projection optical system |
Cited By (2)
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CN101833166B (en) * | 2009-03-13 | 2011-10-05 | 扬明光学股份有限公司 | Lens |
TWI652509B (en) | 2016-12-23 | 2019-03-01 | 鴻海精密工業股份有限公司 | Method for designing optical system used for bevel camera |
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