CN104749752A - Wide-view-field and high-resolution projection objective lens - Google Patents
Wide-view-field and high-resolution projection objective lens Download PDFInfo
- Publication number
- CN104749752A CN104749752A CN201510184356.XA CN201510184356A CN104749752A CN 104749752 A CN104749752 A CN 104749752A CN 201510184356 A CN201510184356 A CN 201510184356A CN 104749752 A CN104749752 A CN 104749752A
- Authority
- CN
- China
- Prior art keywords
- lens
- mirror group
- projection objective
- visual field
- refractive index
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Classifications
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B13/00—Optical objectives specially designed for the purposes specified below
- G02B13/22—Telecentric objectives or lens systems
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B13/00—Optical objectives specially designed for the purposes specified below
- G02B13/001—Miniaturised objectives for electronic devices, e.g. portable telephones, webcams, PDAs, small digital cameras
- G02B13/0015—Miniaturised objectives for electronic devices, e.g. portable telephones, webcams, PDAs, small digital cameras characterised by the lens design
- G02B13/002—Miniaturised objectives for electronic devices, e.g. portable telephones, webcams, PDAs, small digital cameras characterised by the lens design having at least one aspherical surface
- G02B13/0035—Miniaturised objectives for electronic devices, e.g. portable telephones, webcams, PDAs, small digital cameras characterised by the lens design having at least one aspherical surface having three lenses
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B13/00—Optical objectives specially designed for the purposes specified below
- G02B13/06—Panoramic objectives; So-called "sky lenses" including panoramic objectives having reflecting surfaces
Landscapes
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Optics & Photonics (AREA)
- Lenses (AREA)
Abstract
The invention discloses a wide-view-field and high-resolution projection objective lens. The projection objective lens sequentially comprises a first lens group, a second lens group and a third lens group from an object side to an image side. A diaphragm and equivalent parallel plates are disposed between the first lens group and the third lens group. The second lens group at least comprises two air lenses satisfying |(r21-r22)/(r21+r22)|<0.6, |(Vd21-Vd22)|>28 and |(nd21-nd22)|>0.09, wherein the curvature radius, dispersion coefficient and d-line refraction rate of the lens surfaces on two sides of the air lenses are respectively r21, r22, Vd21, Vd22, nd21 and nd22. The second lens group further at least comprises two positive lenses satisfying dn/dt<0 under room temperature, wherein n is refraction rate, t is temperature, and dn/dt is the refraction rate temperature coefficient indicating the refraction rate change of optical materials along with temperature change.
Description
Technical field
The present invention relates to a kind of projection objective, particularly relate to a kind of wide visual field high resolving power projection objective of high precision Large visual angle optical detection, be applied to research and the detection of the high-resolution Large visual angle in the fields such as biology, heredity, medical treatment and medicine.
Background technology
Be applied to the development of the researchs such as biology, heredity, medical treatment and medicine and detection technique, the projection objective demand that the optical detection of high precision Large visual angle requires strengthens day by day.Have simultaneously wide spectral, high-resolution, Large visual angle 3 kinds of performances the Design and manufacture of projection objective very difficult, also rare precedent at present.
Summary of the invention
For the deficiencies in the prior art, the object of the present invention is to provide a kind of wide visual field high resolving power projection objective, achieve the spherical aberration of projection objective, coma, astigmatism, every aberration such as axial chromatic aberation and multiplying power chromatic aberation etc. all obtains well-corrected, especially correct good to the second order spectrum of axial chromatic aberration, the processing of camera lens can be reduced again, the difficulty in test and dress school and cost, simultaneously having good image space heart projection objective far away effect, for capture below provides good condition.
The present invention realizes by the following technical solutions: a kind of wide visual field high resolving power projection objective, and its from thing side (P1) to image side (P2) comprises the first mirror group (G1), the second mirror group (G2), the 3rd mirror group (G3) successively;
In the second mirror group (G2), meet relational expression: Vd=(nd-1)/(nF-nC), nd < 1.65 and the rarest two of the positive lens of Vd > 62, nd > 1.50 and the rarest one of the negative lens of Vd < 55; Wherein, Vd is abbe number, the constant of dispersion degree embodying optical material, and nF is the F line refractive index of Bo Long 486nm, and nd is the d line refractive index of Bo Long 587nm, and nC is the C line refractive index of Bo Long 656nm;
Relational expression is met: 0.3<f1/fa<2.8 between first mirror group (G1), the second mirror group (G2), each mirror group of the 3rd mirror group (G3), 0.25<f2/fa<2.5,0.25<-f3/fa<5.5; Wherein, f1 is the combined focal length of the first mirror group (G1), and f2 is the combined focal length of the second mirror group (G2), and f3 is the combined focal length of the 3rd mirror group (G3), and fa is the combined focal length of whole projection objective;
Wherein, between the first mirror group (G1) and the 3rd mirror group (G3), diaphragm (AS) is provided with; Equivalent parallel plate (PLATE) is provided with between thing side (P1) and image side (P2), equivalent parallel plate meets: Tpl > 0.6Dop, wherein, Tpl is equivalent parallel plate thickness, and Dop is the maximum clear aperture of equivalent parallel plate;
In the second mirror group (G2), also at least meet relational expression containing two air-lens: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | > 0.09; Wherein, r21, r22 are respectively the radius-of-curvature of the lens surface of air-lens both sides, and Vd21, Vd22 are respectively the abbe number of the lens of air-lens both sides, and nd21, nd22 are respectively the d line refractive index of the lens of the both sides of air-lens; And the second mirror group (G2) at least meets at ambient temperature containing two positive lenss: dn/dt < 0; Wherein, n is refractive index, and t is temperature, and dn/dt is the temperature variant thermal refractive index coefficient of refractive index of optical material;
Image side (P2) has the concave spherical surface towards thing side (P1), and meets: α in<NA/ β, 0.8<Lpout/Rim<1.2; Wherein, α in is the incident angle of chief ray at image side (P2) of projection objective, and NA is the object-side numerical aperture of projection objective, β is the enlargement ratio of projection objective, get on the occasion of, Lpout is the radius-of-curvature of projection objective image space distance of exit pupil, Rim image planes concave spherical surface.
As the further improvement of such scheme, in the 3rd mirror group (G3), containing the concave surface one that a pair faces one another, and at least containing a negative lens between the described concave surface one faced one another for a pair, and described negative lens contains the concave surface two towards thing side; 3rd mirror group (G3) also meets relational expression: at least meet ndp > ndn containing a positive lens and a negative lens, at least meets Vdp < Vdn containing a positive lens and a negative lens; Wherein, ndp is the d line refractive index of described positive lens, and ndn is the d line refractive index of described negative lens, and Vdp is the abbe number of described positive lens, and Vdn is the abbe number of described negative lens.
As the further improvement of such scheme, in the first mirror group (G1): at least meet containing a positive lens and a negative lens: ndp > ndn; At least meet containing a positive lens and a negative lens: Vdp < Vdn.
As the further improvement of such scheme, 4< β <18.
Further, the lens total quantity of described wide visual field high resolving power projection objective is between 12 to 28.
As the further improvement of such scheme, described equivalent parallel plate is arranged between the first mirror group (G1) and the 3rd mirror group (G3), and described equivalent parallel plate is the divided beams device with fractional transmission and part reflection.
As the further improvement of such scheme, all lens surfaces in first mirror group (G1), the second mirror group (G2), the 3rd mirror group (G3) are sphere, not containing aspheric surface, the simple lens that the second mirror group (G2), the 3rd mirror group (G3) are not containing cemented surface forms.
As the further improvement of such scheme, the second mirror group (G2) comprises at least two lens with negative power and wherein at least one lens is biconcave lens; Also comprise at least three lens with positive light coke and wherein at least two lens are biconvex lens.
As the further improvement of such scheme, the 3rd mirror group (G3) comprises at least two lens with negative power; Also comprise at least two lens with positive light coke and comprise at least one crescent lens.
As the further improvement of such scheme, the openings of sizes of diaphragm can regulate.
Advantage of the present invention: 1, has wide spectral, high-resolution, Large visual angle 3 kinds of characteristics simultaneously, current also rare precedent; 2, there is good image space heart projection objective far away effect, for later capture provides good condition; 3, the greatest optical bore of projection objective only has about 60% of image space full filed bore, considerably reduces manufacturing cost and the difficulty of projection objective.And the greatest optical bore of common image space heart projection objective far away is more than 100% of image space full filed bore, manufacturing cost is high and manufacture difficulty is large; 4, eyeglass bore is little, does not comprise aspherical lens, considerably reduces processing, detects and fill difficulty and the cost in school; 5, the fractional transmission of equivalent parallel plate and the light splitting function of part reflection can be utilized, realize variously coaxially falling to penetrating illumination.
Accompanying drawing explanation
The structural representation of the wide visual field high resolving power projection objective that Fig. 1 provides for the embodiment of the present invention 1.
Fig. 2 is the structural representation of air-lens.
Fig. 3 is 0.7 aperture place axial chromatic aberration curve map of wide visual field high resolving power projection objective in Fig. 1.
Fig. 4 is that in Fig. 1, wide visual field high resolving power projection objective is schemed at the transport function MTF of 480-730nm wavelength coverage.
The structural representation of the wide visual field high resolving power projection objective that Fig. 5 provides for the embodiment of the present invention 2.
Fig. 6 is 0.7 aperture place axial chromatic aberration curve map of wide visual field high resolving power projection objective in Fig. 5.
Fig. 7 is that in Fig. 5, wide visual field high resolving power projection objective is schemed at the transport function MTF of 480-730nm wavelength coverage.
The structural representation of the wide visual field high resolving power projection objective that Fig. 8 provides for the embodiment of the present invention 3.
Fig. 9 is 0.7 aperture place axial chromatic aberration curve map of wide visual field high resolving power projection objective in Fig. 8.
Figure 10 is that in Fig. 8, wide visual field high resolving power projection objective is schemed at the transport function MTF of 480-730nm wavelength coverage.
The structural representation of the wide visual field high resolving power projection objective that Figure 11 provides for the embodiment of the present invention 4.
Figure 12 is 0.7 aperture place axial chromatic aberration curve map of wide visual field high resolving power projection objective in Fig. 4.
Figure 13 is that in Fig. 4, wide visual field high resolving power projection objective is schemed at the transport function MTF of 480-730nm wavelength coverage.
Embodiment
In order to make object of the present invention, technical scheme and advantage clearly understand, below in conjunction with drawings and Examples, the present invention is further elaborated.Should be appreciated that specific embodiment described herein only in order to explain the present invention, be not intended to limit the present invention.
Embodiment 1
Refer to Fig. 1, the structural representation of its wide visual field high resolving power projection objective provided for the embodiment of the present invention 1.Wide visual field high resolving power projection objective comprises the first mirror group G1, equivalent parallel plate PLATE, the second mirror group G2, the 3rd mirror group G3 successively from thing side P1 to image side P2.In the second mirror group G2, be provided with diaphragm AS, the openings of sizes of diaphragm AS can regulate, and can adopt the adjustable diaphragm of openings of sizes.Equivalent parallel plate PLATE is between thing side P1 and image side P2.
From thing side P1 to image side P2, the first mirror group G1 can comprise the first lens L1, the second lens L2, the 3rd lens L3, the 4th lens L4 successively.Second mirror group G2 can comprise at least two lens with negative power and wherein at least one lens is biconcave lens; Also can comprise at least three lens with positive light coke and wherein at least two lens are biconvex lens.In the present embodiment, from thing side P1 to image side P2, the second mirror group G2 comprises the 5th lens L5, the 6th lens L6, the 7th lens L7, the 8th lens L8, the 9th lens L9, the tenth lens L10, the 11 lens L11 successively.3rd mirror group G3 can comprise at least two lens with negative power; Also can comprise at least two lens with positive light coke and comprise at least one crescent lens.In the present embodiment, from thing side P1 to image side P2, the 3rd mirror group G3 comprises the 12 lens L12, the 13 lens L13, the 14 lens L14, the 15 lens L15, the 16 lens L16, the 17 lens L17 successively.
Wherein, the first lens L1, the 3rd lens L3, the 6th lens L6, the 9th lens L9, the 13 lens L13, the 14 lens L14, the 15 lens L15 all have negative power.Second lens L2, the 4th lens L4, the 5th lens L5, the 7th lens L7, the 8th lens L8, the tenth lens L10, the 11 lens L11, the 12 lens L12, the 16 lens L16, the 17 lens L17 all have positive light coke.
In the present embodiment, the component parameters of first to the 17 lens L1 ~ L17 is as shown in table 1.
Table 1 projection objective parameter
Relational expression is met: 0.3<f1/fa<2.8 between first mirror group G1, the second mirror group G2, each mirror group of the 3rd mirror group G3,0.25<f2/fa<2.5,0.25<-f3/fa<5.5.Wherein, f1 is the combined focal length of the first mirror group G1, and f2 is the combined focal length of the second mirror group G2, and f3 is the combined focal length of the 3rd mirror group G3, and fa is the combined focal length of whole projection objective.Such lens structure can make the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, and every aberrations such as axial chromatic aberation and multiplying power chromatic aberation are all rationally corrected.In the present embodiment, f1/fa=0.211, f2/fa=0.282 ,-f3/fa=0.150.
In the first mirror group G1, at least meet containing a positive lens and a negative lens: ndp > ndn, at least meet containing a positive lens and a negative lens: Vdp < Vdn.Wherein, ndp is the d line refractive index of described positive lens, and ndn is the d line refractive index of described negative lens, and Vdp is the abbe number of described positive lens, and Vdn is the abbe number of described negative lens.The Main Function that first mirror group G1 designs like this is the elementary and high-order spherical aberration correcting projection objective, the second order spectrum aberration of the axial chromatic aberration of balance projection objective, the ratio chromatism, of auxiliary balance projection objective.
In the second mirror group G2, meet relational expression: 1. Vd=(nd-1)/(nF-nC); 2. nd < 1.65 and the rarest two of the positive lens of Vd > 62; 3. nd > 1.50 and the rarest one of the negative lens of Vd < 55; 4. at least relational expression is met containing two air-lens: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | > 0.09; 5. the second mirror group (G2) at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Wherein, Vd is abbe number, the constant of dispersion degree embodying optical material, and nF is the F line refractive index of Bo Long 486nm, and nd is the d line refractive index of Bo Long 587nm, and nC is the C line refractive index of Bo Long 656nm; R21, r22 are respectively the radius-of-curvature of the lens surface of air-lens both sides, Vd21, Vd22 are respectively the abbe number of the lens of air-lens both sides, nd21, nd22 are respectively the d line refractive index of the lens of the both sides of air-lens, n is refractive index, t is temperature, and dn/dt is the temperature variant thermal refractive index coefficient of refractive index of optical material.
For air-lens, in the lens group forming camera lens, can be regarded as the lens as refractive index 1.0 by air space (air space) L that adjacent two glass lenss are clipped in the middle, the air space designed in view of this consideration can be described as air-lens, air-lens L as shown in Figure 2.The front and back index of refraction relationship of air-lens L is that glass lens Lx, the Ly respectively with adjacent is contrary, and therefore convex surface has concavees lens effect, and concave surface has the effect of convex lens.Please again consult Fig. 1, in the present embodiment, between lens L6, L7 of second mirror group L2, between lens L8, L9, article namely all exist between lens L9, L10 and meet the 4.: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | the air-lens of > 0.09.As relational expression | (r21-r22)/(r21+r22) | calculated value be respectively 0.211,0.282 and 0.150, meet relational expression | (r21-r22)/(r21+r22) | <0.6.Main Function is the elementary and high-order spherical aberration and the coma that correct projection objective, corrects the axial chromatic aberration of projection objective simultaneously and effectively reduces its second order spectrum aberration; Effectively reduce amber hereby to cut down (Petzval) and make the curvature of the image of projection objective to obtain well-corrected.
Second mirror group L2 the 5. article namely: the second mirror group G2 at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Different from dn/dt > 0 characteristic of general optical glass material, when having positive lens to meet dn/dt < 0, contrary with the characteristic of the thermal refractive index coefficient of other general optical glass lens, cancel each other, so the thermal stability of projection objective can be improved, make projection objective when variation of ambient temperature, its image planes position and image quality keep stable.
In the 3rd mirror group G3, containing the concave surface one that a pair faces one another, and at least containing a negative lens between the described concave surface one faced one another for a pair, and described negative lens contains the concave surface two towards thing side P1.3rd mirror group G3 also meets relational expression: at least meet ndp > ndn containing a positive lens and a negative lens, at least meets Vdp < Vdn containing a positive lens and a negative lens.The Main Function that 3rd mirror group G3 designs like this is the elementary and senior astigmatism of balance projection objective and contributes to reducing the second order spectrum aberration of axial chromatic aberration, balances the ratio chromatism, of projection objective.In the present embodiment, the concave surface one faced one another for a pair is there is between 13 lens L13 and the 15 lens L15, namely the 13 lens L13 is concave surface towards the curved surface of the 15 lens L15, and the 15 lens L15 is also concave surface towards the curved surface of the 13 lens L13.Between this is to the concave surface one faced one another, exist for the 14 lens L14 of negative lens, the 14 lens L14 contains the concave surface two towards thing side P1, and namely the 14 lens L14 is also concave surface towards the curved surface of thing side P1.
In order to eliminate the internal stress of optical mirror slip, thermal stress and aging, and to the harmful effect that optical imagery causes, keep the stability of projection objective, all lens surfaces in first mirror group G1, the second mirror group G2, the 3rd mirror group G3 are sphere, not containing aspheric surface, the simple lens that the second mirror group G2, the 3rd mirror group G3 are not containing cemented surface forms.In addition, do not comprise aspherical lens, significantly can reduce processing, detect and fill difficulty and the cost in school.
In order to good image space heart projection objective far away effect can be obtained, for later capture provides good condition, image side P2 has the concave spherical surface towards thing side P1, and meets: α in<NA/ β, 0.8<Lpout/Rim<1.2; Wherein, α in is the incident angle of chief ray at image side P2 of projection objective, and NA is the object-side numerical aperture of projection objective, and β is the enlargement ratio of projection objective, and Lpout is the radius-of-curvature of projection objective image space distance of exit pupil, Rim image planes concave spherical surface.
In the present embodiment, the parameter value of projection objective: β=10; NA=0.35; Hy=21.2; Spectral range: 470-750nm.Wherein, β is projection multiplying power, 4< β <18; NA is thing side opening number; Hy is maximum object height.
Equivalent parallel plate is provided with (in the present embodiment between the first mirror group G1 and the 3rd mirror group G3, equivalent parallel plate is between the first mirror group G1 and the second mirror group G2), equivalent parallel plate meets: Tpl > 0.6Dop.Wherein, Tpl is equivalent parallel plate thickness, Dop is the maximum clear aperture of equivalent parallel plate, equivalent parallel plate is the divided beams device with fractional transmission and part reflection, its Main Function to utilize the fractional transmission of equivalent parallel plate and the light splitting function of part reflection, realizes variously coaxially falling to penetrating illumination.
In order to the conservative control cost of wide visual field high resolving power projection objective, and obtain best cost performance, the lens total quantity of described wide visual field high resolving power projection objective is between 12 to 28.
In a word, in the present embodiment, three lens cluster adopts such lens structure finally to guarantee and achieves the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, every aberration such as axial chromatic aberation and multiplying power chromatic aberation etc. all obtains well-corrected, effectively can control the greatest optical bore of camera lens simultaneously, reduce the processing of camera lens, the difficulty in test and dress school and cost.
The wide visual field high resolving power projection objective of present embodiment, the axial chromatic aberration of wide visual field high resolving power projection objective as shown in Figure 3, effectively corrects axial chromatic aberration within the scope of broad band, covers 480-730nm wavelength coverage.As can be seen from the figure, the present invention can obtain high imaging quality effectively.The projection objective of wide visual field high resolving power projection objective is schemed as shown in Figure 4 at the transport function MTF of 480-730nm wavelength coverage.Wave aberration WFE (RMS) result of the analysis of specialty optics design software shows: the wave aberration WFE (RMS) of each wavelength is all less than 1/14 of its wavelength, as shown in table 2.
The wave aberration of each wavelength of table 2
Wavelength (nm) | Title | Wave aberration (RMS) |
486.13 | F line | 1/14λ |
546.07 | E line | 1/19λ |
587.56 | D line | 1/21λ |
656.27 | C line | 1/19λ |
706.52 | R line | 1/16λ |
730 | --- | 1/15λ |
480-730 | Wavelength coverage | 1/15λ |
Embodiment 2
Refer to Fig. 5, the structural representation of its wide visual field high resolving power projection objective provided for the embodiment of the present invention 2.Wide visual field high resolving power projection objective comprises the first mirror group G1, the second mirror group G2, the 3rd mirror group G3 successively from thing side P1 to image side P2.In the second mirror group G2, be provided with diaphragm AS, the openings of sizes of diaphragm AS can regulate, and can adopt the adjustable diaphragm of openings of sizes.
From thing side P1 to image side P2, the first mirror group G1 can comprise the first lens L1, the second lens L2, the 3rd lens L3, the 4th lens L4 successively; Second mirror group G2 can comprise the 5th lens L5, the 6th lens L6, the 7th lens L7, the 8th lens L8, the 9th lens L9, the tenth lens L10, the 11 lens L11 successively; 3rd mirror group G3 can comprise the 12 lens L12, the 13 lens L13, the 14 lens L14, the 15 lens L15, the 16 lens L16 successively.
Wherein, the 3rd lens L3, the 6th lens (L6), the 9th lens L9, the 12 lens L12, the 13 lens L13 all have negative power.Second lens L2, the 4th lens L4, the 5th lens L5, the 7th lens L7, the 8th lens L8, the tenth lens L10, the 11 lens L11, the 15 lens L15, the 16 lens L16 all have positive light coke.
In the present embodiment, the component parameters of first to the 16 lens L1 ~ L16 is as shown in table 3.
Table 3 projection objective parameter
Relational expression is met: 0.3<f1/fa<2.8 between first mirror group G1, the second mirror group G2, each mirror group of the 3rd mirror group G3,0.25<f2/fa<2.5,0.25<-f3/fa<5.5.Wherein, f1 is the combined focal length of the first mirror group G1, and f2 is the combined focal length of the second mirror group G2, and f3 is the combined focal length of the 3rd mirror group G3, and fa is the combined focal length of whole projection objective.Such lens structure can make the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, and every aberrations such as axial chromatic aberation and multiplying power chromatic aberation are all rationally corrected.In the present embodiment, f1=238.02, f2=198.01, f3=-450.5, fa=219.8, f1/fa=0.82, f2/fa=0.92 ,-f3/fa=1.68.
In the first mirror group G1, at least meet containing a positive lens and a negative lens: ndp > ndn, at least meet containing a positive lens and a negative lens: Vdp < Vdn.Wherein, ndp is the d line refractive index of described positive lens, and ndn is the d line refractive index of described negative lens, and Vdp is the abbe number of described positive lens, and Vdn is the abbe number of described negative lens.The Main Function that first mirror group G1 designs like this is the elementary and high-order spherical aberration correcting projection objective, the second order spectrum aberration of the axial chromatic aberration of balance projection objective, the ratio chromatism, of auxiliary balance projection objective.
In the second mirror group G2, meet relational expression: 1. Vd=(nd-1)/(nF-nC); 2. nd < 1.65 and the rarest two of the positive lens of Vd > 62; 3. nd > 1.50 and the rarest one of the negative lens of Vd < 55; 4. at least relational expression is met containing two air-lens: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | > 0.09; 5. the second mirror group (G2) at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Wherein, Vd is abbe number, the constant of dispersion degree embodying optical material, and nF is the F line refractive index of Bo Long 486nm, and nd is the d line refractive index of Bo Long 587nm,
The C line refractive index of nC Wei Bo Long 656nm;
R21, r22 are respectively the radius-of-curvature of the lens surface of air-lens both sides,
Vd21, Vd22 are respectively the abbe number of the lens of air-lens both sides,
Nd21, nd22 are respectively the d line refractive index of the lens of the both sides of air-lens, and n is refractive index, and t is temperature, and dn/dt is the temperature variant thermal refractive index coefficient of refractive index of optical material.
In the present embodiment, between lens L6, L7 of second mirror group L2, between lens L8, L9, article namely all exist between lens L9, L10 and meet the 4.: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | the air-lens of > 0.09.As relational expression | (r21-r22)/(r21+r22) | calculated value be respectively 0.203,0.035 and 0.184, meet relational expression | (r21-r22)/(r21+r22) | <0.6.Main Function is the elementary and high-order spherical aberration and the coma that correct projection objective, corrects the axial chromatic aberration of projection objective simultaneously and effectively reduces its second order spectrum aberration; Effectively reduce amber hereby to cut down (Petzval) and make the curvature of the image of projection objective to obtain well-corrected.
Second mirror group L2 the 5. article namely: the second mirror group G2 at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Different from dn/dt > 0 characteristic of general optical glass material, when having positive lens to meet dn/dt < 0, contrary with the characteristic of the thermal refractive index coefficient of other general optical glass lens, cancel each other, so the thermal stability of projection objective can be improved, make projection objective when variation of ambient temperature, its image planes position and image quality keep stable.
In the 3rd mirror group G3, containing the concave surface one that a pair faces one another, and at least containing a negative lens between the described concave surface one faced one another for a pair, and described negative lens contains the concave surface two towards thing side P1.3rd mirror group G3 also meets relational expression: at least meet ndp > ndn containing a positive lens and a negative lens, at least meets Vdp < Vdn containing a positive lens and a negative lens.The Main Function that 3rd mirror group G3 designs like this is the elementary and senior astigmatism of balance projection objective and contributes to reducing the second order spectrum aberration of axial chromatic aberration, balances the ratio chromatism, of projection objective.In the present embodiment, the concave surface one faced one another for a pair is there is between 12 lens L12 and the 14 lens L14, namely the 12 lens L12 is concave surface towards the curved surface of the 14 lens L14, and the 14 lens L14 is also concave surface towards the curved surface of the 12 lens L12.Between this is to the concave surface one faced one another, exist for the 13 lens L13 of negative lens, the 13 lens L13 contains the concave surface two towards thing side P1, and namely the 13 lens L13 is also concave surface towards the curved surface of thing side P1.
In order to eliminate the internal stress of optical mirror slip, thermal stress and aging, and to the harmful effect that optical imagery causes, keep the stability of projection objective, all lens surfaces in first mirror group G1, the second mirror group G2, the 3rd mirror group G3 are sphere, not containing aspheric surface, the simple lens that the second mirror group G2, the 3rd mirror group G3 are not containing cemented surface forms.In addition, do not comprise aspherical lens, significantly can reduce processing, detect and fill difficulty and the cost in school.
In order to the conservative control cost of wide visual field high resolving power projection objective, and obtain best cost performance, the lens total quantity of described wide visual field high resolving power projection objective is between 12 to 28.
In a word, in the present embodiment, three lens cluster adopts such lens structure finally to guarantee and achieves the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, every aberration such as axial chromatic aberation and multiplying power chromatic aberation etc. all obtains well-corrected, effectively can control the greatest optical bore of camera lens simultaneously, reduce the processing of camera lens, the difficulty in test and dress school and cost.
The wide visual field high resolving power projection objective of present embodiment, the axial chromatic aberration of wide visual field high resolving power projection objective as shown in Figure 6, effectively corrects axial chromatic aberration within the scope of broad band, covers 480-730nm wavelength coverage.As can be seen from the figure, the present invention can obtain high imaging quality effectively.The projection objective of wide visual field high resolving power projection objective is schemed as shown in Figure 7 at the transport function MTF of 480-730nm wavelength coverage.Wave aberration WFE (RMS) result of the analysis of specialty optics design software shows: be all less than 1/15 of wavelength at the wave aberration WFE (RMS) of 480-730nm wavelength coverage, as shown in table 4.
The wave aberration of each wavelength of table 4
Wavelength (nm) | Title | Wave aberration (RMS) | Wave aberration (RMS) |
486.13 | F line | 1/10λ | 0.097λ |
546.07 | E line | 1/20λ | 0.049λ |
587.56 | D line | 1/17λ | 0.06λ |
656.27 | C line | 1/14λ | 0.072λ |
706.52 | R line | 1/12λ | 0.084λ |
730 | --- | 1/11λ | 0.088λ |
480-730 | Wavelength coverage | 1/15λ | 0.065λ |
Embodiment 3
Refer to Fig. 8, the structural representation of its wide visual field high resolving power projection objective provided for the embodiment of the present invention 3.Wide visual field high resolving power projection objective comprises the first mirror group G1, the second mirror group G2, the 3rd mirror group G3 successively from thing side P1 to image side P2.In the second mirror group G2, be provided with diaphragm AS, the openings of sizes of diaphragm AS can regulate, and can adopt the adjustable diaphragm of openings of sizes.
From thing side P1 to image side P2, the first mirror group G1 can comprise the first lens L1, the second lens L2, the 3rd lens L3, the 4th lens L4 successively.Second mirror group G2 can comprise at least two lens with negative power and wherein at least one lens is biconcave lens; Also can comprise at least three lens with positive light coke and wherein at least two lens are biconvex lens.In the present embodiment, from thing side P1 to image side P2, the second mirror group G2 comprises the 5th lens L5, the 6th lens L6, the 7th lens L7, the 8th lens L8, the 9th lens L9, the tenth lens L10, the 11 lens L11 successively.3rd mirror group G3 can comprise at least two lens with negative power; Also can comprise at least two lens with positive light coke and comprise at least one crescent lens.In the present embodiment, from thing side P1 to image side P2, the 3rd mirror group G3 comprises the 12 lens L12, the 13 lens L13, the 14 lens L14, the 15 lens L15, the 16 lens L16 successively.
Wherein, the 3rd lens L3, the 6th lens (L6), the 9th lens L9, the 12 lens L12, the 13 lens L13 all have negative power.Second lens L2, the 4th lens L4, the 5th lens L5, the 7th lens L7, the 8th lens L8, the tenth lens L10, the 11 lens L11, the 15 lens L15, the 16 lens L16 all have positive light coke.
In the present embodiment, the component parameters of first to the 16 lens L1 ~ L16 is as shown in table 5.
Table 5 projection objective parameter
Relational expression is met: 0.3<f1/fa<2.8 between first mirror group G1, the second mirror group G2, each mirror group of the 3rd mirror group G3,0.25<f2/fa<2.5,0.25<-f3/fa<5.5.Wherein, f1 is the combined focal length of the first mirror group G1, and f2 is the combined focal length of the second mirror group G2, and f3 is the combined focal length of the 3rd mirror group G3, and fa is the combined focal length of whole projection objective.Such lens structure can make the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, and every aberrations such as axial chromatic aberation and multiplying power chromatic aberation are all rationally corrected.In the present embodiment, f1/fa=0.82, f2/fa=0.82 ,-f3/fa=2.06.
In the first mirror group G1, at least meet containing a positive lens and a negative lens: ndp > ndn, at least meet containing a positive lens and a negative lens: Vdp < Vdn.Wherein, ndp is the d line refractive index of described positive lens, and ndn is the d line refractive index of described negative lens, and Vdp is the abbe number of described positive lens, and Vdn is the abbe number of described negative lens.The Main Function that first mirror group G1 designs like this is the elementary and high-order spherical aberration correcting projection objective, the second order spectrum aberration of the axial chromatic aberration of balance projection objective, the ratio chromatism, of auxiliary balance projection objective.
In the second mirror group G2, meet relational expression: 1. Vd=(nd-1)/(nF-nC); 2. nd < 1.65 and the rarest two of the positive lens of Vd > 62; 3. nd > 1.50 and the rarest one of the negative lens of Vd < 55; 4. at least relational expression is met containing two air-lens: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | > 0.09; 5. the second mirror group (G2) at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Wherein, Vd is abbe number, the constant of dispersion degree embodying optical material, and nF is the F line refractive index of Bo Long 486nm, and nd is the d line refractive index of Bo Long 587nm, and nC is the C line refractive index of Bo Long 656nm; R21, r22 are respectively the radius-of-curvature of the lens surface of air-lens both sides, Vd21, Vd22 are respectively the abbe number of the lens of air-lens both sides, nd21, nd22 are respectively the d line refractive index of the lens of the both sides of air-lens, n is refractive index, t is temperature, and dn/dt is the temperature variant thermal refractive index coefficient of refractive index of optical material.
In the present embodiment, between lens L6, L7 of second mirror group L2, between lens L8, L9, article namely all exist between lens L9, L10 and meet the 4.: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | the air-lens of > 0.09.As relational expression | (r21-r22)/(r21+r22) | calculated value be respectively 0.247,0.054 and 0.166, meet relational expression | (r21-r22)/(r21+r22) | <0.6.Main Function is the elementary and high-order spherical aberration and the coma that correct projection objective, corrects the axial chromatic aberration of projection objective simultaneously and effectively reduces its second order spectrum aberration; Effectively reduce amber hereby to cut down (Petzval) and make the curvature of the image of projection objective to obtain well-corrected.
Second mirror group L2 the 5. article namely: the second mirror group G2 at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Different from dn/dt > 0 characteristic of general optical glass material, when having positive lens to meet dn/dt < 0, contrary with the characteristic of the thermal refractive index coefficient of other general optical glass lens, cancel each other, so the thermal stability of projection objective can be improved, make projection objective when variation of ambient temperature, its image planes position and image quality keep stable.
In the 3rd mirror group G3, containing the concave surface one that a pair faces one another, and at least containing a negative lens between the described concave surface one faced one another for a pair, and described negative lens contains the concave surface two towards thing side P1.3rd mirror group G3 also meets relational expression: at least meet ndp > ndn containing a positive lens and a negative lens, at least meets Vdp < Vdn containing a positive lens and a negative lens.The Main Function that 3rd mirror group G3 designs like this is the elementary and senior astigmatism of balance projection objective and contributes to reducing the second order spectrum aberration of axial chromatic aberration, balances the ratio chromatism, of projection objective.In the present embodiment, the concave surface one faced one another for a pair is there is between 12 lens L12 and the 14 lens L14, namely the 12 lens L12 is concave surface towards the curved surface of the 14 lens L14, and the 14 lens L14 is also concave surface towards the curved surface of the 12 lens L12.Between this is to the concave surface one faced one another, exist for the 13 lens L13 of negative lens, the 13 lens L13 contains the concave surface two towards thing side P1, and namely the 13 lens L13 is also concave surface towards the curved surface of thing side P1.
In order to eliminate the internal stress of optical mirror slip, thermal stress and aging, and to the harmful effect that optical imagery causes, keep the stability of projection objective, all lens surfaces in first mirror group G1, the second mirror group G2, the 3rd mirror group G3 are sphere, not containing aspheric surface, the simple lens that the second mirror group G2, the 3rd mirror group G3 are not containing cemented surface forms.In addition, do not comprise aspherical lens, significantly can reduce processing, detect and fill difficulty and the cost in school.
In order to good image space heart projection objective far away effect can be obtained, for later capture provides good condition, image side P2 has the concave spherical surface towards thing side P1, and meets: α in<NA/ β, 0.8<Lpout/Rim<1.2; Wherein, α in is the incident angle of chief ray at image side P2 of projection objective, and NA is the object-side numerical aperture of projection objective, and β is the enlargement ratio of projection objective, and Lpout is the radius-of-curvature of projection objective image space distance of exit pupil, Rim image planes concave spherical surface.
In the present embodiment, the parameter value of projection objective: β=10; NA=0.35; Hy=21.2; Spectral range: 470-750nm.Wherein, β is projection multiplying power, 4< β <18; NA is thing side opening number; Hy is maximum object height.
In order to the conservative control cost of wide visual field high resolving power projection objective, and obtain best cost performance, the lens total quantity of described wide visual field high resolving power projection objective is between 12 to 28.
In a word, in the present embodiment, three lens cluster adopts such lens structure finally to guarantee and achieves the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, every aberration such as axial chromatic aberation and multiplying power chromatic aberation etc. all obtains well-corrected, effectively can control the greatest optical bore of camera lens simultaneously, reduce the processing of camera lens, the difficulty in test and dress school and cost.
The wide visual field high resolving power projection objective of present embodiment, the axial chromatic aberration of wide visual field high resolving power projection objective as shown in Figure 9, effectively corrects axial chromatic aberration within the scope of broad band, covers 480-730nm wavelength coverage.As can be seen from the figure, the present invention can obtain high imaging quality effectively.The projection objective of wide visual field high resolving power projection objective is schemed as shown in Figure 10 at the transport function MTF of 480-730nm wavelength coverage.Wave aberration WFE (RMS) result of the analysis of specialty optics design software shows: the wave aberration WFE (RMS) of each wavelength is all less than 1/14 of its wavelength, as shown in table 6.
The wave aberration of each wavelength of table 6.
Wavelength (nm) | Title | Wave aberration (RMS) | Wave aberration (RMS) |
486.13 | F line | 1/9λ | 0.11λ |
546.07 | E line | 1/19λ | 0.053λ |
587.56 | D line | 1/18λ | 0.055λ |
656.27 | C line | 1/14λ | 0.073λ |
706.52 | R line | 1/11λ | 0.09λ |
730 | --- | 1/10λ | 0.1λ |
480-730 | Wavelength coverage | 1/14λ | 0.072λ |
Embodiment 4
Refer to Figure 11, the structural representation of its wide visual field high resolving power projection objective provided for the embodiment of the present invention 4.Wide visual field high resolving power projection objective comprises the first mirror group G1, equivalent parallel plate PLATE, the second mirror group G2, the 3rd mirror group G3 successively from thing side P1 to image side P2.In the second mirror group G2, be provided with diaphragm AS, the openings of sizes of diaphragm AS can regulate, and can adopt the adjustable diaphragm of openings of sizes.
From thing side P1 to image side P2, the first mirror group G1 can comprise the first lens L1, the second lens L2, the 3rd lens L3, the 4th lens L4 successively; Second mirror group G2 can comprise the 5th lens L5, the 6th lens L6, the 7th lens L7, the 8th lens L8, the 9th lens L9, the tenth lens L10, the 11 lens L11 successively; 3rd mirror group G3 can comprise the 12 lens L12, the 13 lens L13, the 14 lens L14, the 15 lens L15, the 16 lens L16, the 17 lens L17 successively.
Wherein, the first lens L1, the 3rd lens L3, the 6th lens (L6), the 9th lens L9, the 13 lens L13, the 14 lens L14, the 15 lens L15 all have negative power.Second lens L2, the 4th lens L4, the 5th lens L5, the 7th lens L7, the 8th lens L8, the tenth lens L10, the 11 lens L11, the 12 lens L12, the 16 lens L16, the 17 lens L17 all have positive light coke.
In the present embodiment, the component parameters of first to the 17 lens L1 ~ L17 is as shown in table 7.
Table 7 projection objective parameter
Relational expression is met: 0.3<f1/fa<2.8 between first mirror group G1, the second mirror group G2, each mirror group of the 3rd mirror group G3,0.25<f2/fa<2.5,0.25<-f3/fa<5.5.Wherein, f1 is the combined focal length of the first mirror group G1, and f2 is the combined focal length of the second mirror group G2, and f3 is the combined focal length of the 3rd mirror group G3, and fa is the combined focal length of whole projection objective.Such lens structure can make the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, and every aberrations such as axial chromatic aberation and multiplying power chromatic aberation are all rationally corrected.In the present embodiment, f1/fa=1.18, f2/fa=0.90 ,-f3/fa=2.02.
In the first mirror group G1, at least meet containing a positive lens and a negative lens: ndp > ndn, at least meet containing a positive lens and a negative lens: Vdp < Vdn.Wherein, ndp is the d line refractive index of described positive lens, and ndn is the d line refractive index of described negative lens, and Vdp is the abbe number of described positive lens, and Vdn is the abbe number of described negative lens.The Main Function that first mirror group G1 designs like this is the elementary and high-order spherical aberration correcting projection objective, the second order spectrum aberration of the axial chromatic aberration of balance projection objective, the ratio chromatism, of auxiliary balance projection objective.
In the second mirror group G2, meet relational expression: 1. Vd=(nd-1)/(nF-nC); 2. nd < 1.65 and the rarest two of the positive lens of Vd > 62; 3. nd > 1.50 and the rarest one of the negative lens of Vd < 55; 4. at least relational expression is met containing two air-lens: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | > 0.09; 5. the second mirror group (G2) at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Wherein, Vd is abbe number, the constant of dispersion degree embodying optical material, and nF is the F line refractive index of Bo Long 486nm, and nd is the d line refractive index of Bo Long 587nm, and nC is the C line refractive index of Bo Long 656nm; R21, r22 are respectively the radius-of-curvature of the lens surface of air-lens both sides, Vd21, Vd22 are respectively the abbe number of the lens of air-lens both sides, nd21, nd22 are respectively the d line refractive index of the lens of the both sides of air-lens, n is refractive index, t is temperature, and dn/dt is the temperature variant thermal refractive index coefficient of refractive index of optical material.
In the present embodiment, between lens L6, L7 of second mirror group L2, between lens L8, L9, article namely all exist between lens L9, L10 and meet the 4.: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | the air-lens of > 0.09.As relational expression | (r21-r22)/(r21+r22) | calculated value be respectively 0.220,0.264 and 0.166, meet relational expression | (r21-r22)/(r21+r22) | <0.6.Main Function is the elementary and high-order spherical aberration and the coma that correct projection objective, corrects the axial chromatic aberration of projection objective simultaneously and effectively reduces its second order spectrum aberration; Effectively reduce amber hereby to cut down (Petzval) and make the curvature of the image of projection objective to obtain well-corrected.
Second mirror group L2 the 5. article namely: the second mirror group G2 at least meets at ambient temperature containing two positive lenss: dn/dt < 0.Different from dn/dt > 0 characteristic of general optical glass material, when having positive lens to meet dn/dt < 0, contrary with the characteristic of the thermal refractive index coefficient of other general optical glass lens, cancel each other, so the thermal stability of projection objective can be improved, make projection objective when variation of ambient temperature, its image planes position and image quality keep stable.
In the 3rd mirror group G3, containing the concave surface one that a pair faces one another, and at least containing a negative lens between the described concave surface one faced one another for a pair, and described negative lens contains the concave surface two towards thing side P1.3rd mirror group G3 also meets relational expression: at least meet ndp > ndn containing a positive lens and a negative lens, at least meets Vdp < Vdn containing a positive lens and a negative lens.The Main Function that 3rd mirror group G3 designs like this is the elementary and senior astigmatism of balance projection objective and contributes to reducing the second order spectrum aberration of axial chromatic aberration, balances the ratio chromatism, of projection objective.In the present embodiment, the concave surface one faced one another for a pair is there is between 13 lens L13 and the 15 lens L15, namely the 13 lens L13 is concave surface towards the curved surface of the 15 lens L15, and the 15 lens L15 is also concave surface towards the curved surface of the 13 lens L13.Between this is to the concave surface one faced one another, exist for the 14 lens L14 of negative lens, the 14 lens L14 contains the concave surface two towards thing side P1, and namely the 14 lens L14 is also concave surface towards the curved surface of thing side P1.
In order to eliminate the internal stress of optical mirror slip, thermal stress and aging, and to the harmful effect that optical imagery causes, keep the stability of projection objective, all lens surfaces in first mirror group G1, the second mirror group G2, the 3rd mirror group G3 are sphere, not containing aspheric surface, the simple lens that the second mirror group G2, the 3rd mirror group G3 are not containing cemented surface forms.In addition, do not comprise aspherical lens, significantly can reduce processing, detect and fill difficulty and the cost in school.
Equivalent parallel plate is provided with (in the present embodiment between the first mirror group G1 and the 3rd mirror group G3, equivalent parallel plate is between the first mirror group G1 and the second mirror group G2), equivalent parallel plate meets: Tpl > 0.6Dop.Wherein, Tpl is equivalent parallel plate thickness, Dop is the maximum clear aperture of equivalent parallel plate, it is the divided beams device with fractional transmission and part reflection that equivalent parallel plate equivalent parallel plate contains one or more layers film, its Main Function to utilize the fractional transmission of equivalent parallel plate and the light splitting function of part reflection, realizes variously coaxially falling to penetrating illumination.
In order to the conservative control cost of wide visual field high resolving power projection objective, and obtain best cost performance, the lens total quantity of described wide visual field high resolving power projection objective is between 12 to 28.
In a word, in the present embodiment, three lens cluster adopts such lens structure finally to guarantee and achieves the spherical aberration of projection objective, coma, astigmatism, filed curvature and distortion, every aberration such as axial chromatic aberation and multiplying power chromatic aberation etc. all obtains well-corrected, effectively can control the greatest optical bore of camera lens simultaneously, reduce the processing of camera lens, the difficulty in test and dress school and cost.
The wide visual field high resolving power projection objective of present embodiment, the axial chromatic aberration of wide visual field high resolving power projection objective as shown in figure 12, effectively corrects axial chromatic aberration within the scope of broad band, covers 480-730nm wavelength coverage.As can be seen from the figure, the present invention can obtain high imaging quality effectively.The projection objective of wide visual field high resolving power projection objective is schemed as shown in figure 13 at the transport function MTF of 480-730nm wavelength coverage.Wave aberration WFE (RMS) result of the analysis of specialty optics design software shows: the wave aberration WFE (RMS) of each wavelength is all less than 1/14 of its wavelength, as shown in table 8.
The wave aberration of each wavelength of table 8.。
Wavelength (nm) | Title | Wave aberration (RMS) | Wave aberration (RMS) |
486.13 | F line | 1/13λ | 0.078λ |
546.07 | E line | 1/18λ | 0.056λ |
587.56 | D line | 1/18λ | 0.055λ |
656.27 | C line | 1/14λ | 0.069λ |
706.52 | R line | 1/12λ | 0.084λ |
730 | --- | 1/11λ | 0.091λ |
480-730 | Wavelength coverage | 1/14λ | 0.071λ |
In sum, the present invention has wide spectral, high-resolution, Large visual angle 3 kinds of characteristics simultaneously, current also rare precedent; There is good image space heart projection objective far away effect, for later capture provides good condition; The greatest optical bore of projection objective only has about 60% of image space full filed bore, considerably reduces manufacturing cost and the difficulty of projection objective.And the greatest optical bore of common image space heart projection objective far away is more than 100% of image space full filed bore, manufacturing cost is high and manufacture difficulty is large; Eyeglass bore is little, does not comprise aspherical lens, considerably reduces processing, detects and fill difficulty and the cost in school; The fractional transmission of equivalent parallel plate and the light splitting function of part reflection can be utilized, realize variously coaxially falling to penetrating illumination.
The foregoing is only preferred embodiment of the present invention, not in order to limit the present invention, all any amendments done within the spirit and principles in the present invention, equivalent replacement and improvement etc., all should be included within protection scope of the present invention.
Claims (10)
1. a wide visual field high resolving power projection objective, its from thing side (P1) to image side (P2) comprises the first mirror group (G1), the second mirror group (G2), the 3rd mirror group (G3) successively; Wherein,
In the second mirror group (G2), meet relational expression: Vd=(nd-1)/(nF-nC), nd < 1.65 and the rarest two of the positive lens of Vd > 62, nd > 1.50 and the rarest one of the negative lens of Vd < 55; Wherein, Vd is abbe number, the constant of dispersion degree embodying optical material, and nF is the F line refractive index of Bo Long 486nm, and nd is the d line refractive index of Bo Long 587nm, and nC is the C line refractive index of Bo Long 656nm;
Relational expression is met: 0.3<f1/fa<2.8 between first mirror group (G1), the second mirror group (G2), each mirror group of the 3rd mirror group (G3), 0.25<f2/fa<2.5,0.25<-f3/fa<5.5; Wherein, f1 is the combined focal length of the first mirror group (G1), and f2 is the combined focal length of the second mirror group (G2), and f3 is the combined focal length of the 3rd mirror group (G3), and fa is the combined focal length of whole projection objective; It is characterized in that:
Diaphragm (AS) is provided with between the first mirror group (G1) and the 3rd mirror group (G3); Equivalent parallel plate (PLATE) is provided with between thing side (P1) and image side (P2), equivalent parallel plate meets: Tpl > 0.6Dop, wherein, Tpl is equivalent parallel plate thickness, and Dop is the maximum clear aperture of equivalent parallel plate;
In the second mirror group (G2), at least meet relational expression containing two air-lens: | (r21-r22)/(r21+r22) | <0.6, | (Vd21-Vd22) | > 28, | (nd21-nd22) | > 0.09; Wherein, r21, r22 are respectively the radius-of-curvature of the lens surface of air-lens both sides, and Vd21, Vd22 are respectively the abbe number of the lens of air-lens both sides, and nd21, nd22 are respectively the d line refractive index of the lens of the both sides of air-lens; And the second mirror group (G2) at least meets at ambient temperature containing two positive lenss: dn/dt < 0; Wherein, n is refractive index, and t is temperature, and dn/dt is the temperature variant thermal refractive index coefficient of refractive index of optical material;
Image side (P2) has the concave spherical surface towards thing side (P1), and meets: α in<NA/ β, 0.8<Lpout/Rim<1.2; Wherein, α in is the incident angle of chief ray at image side (P2) of projection objective, and NA is the object-side numerical aperture of projection objective, β is the enlargement ratio of projection objective, get on the occasion of, Lpout is the radius-of-curvature of projection objective image space distance of exit pupil, Rim image planes concave spherical surface.
2. wide visual field high resolving power projection objective as claimed in claim 1, it is characterized in that: in the 3rd mirror group (G3), containing the concave surface one that a pair faces one another, and at least containing a negative lens between the described concave surface one faced one another for a pair, and described negative lens contains the concave surface two towards thing side; 3rd mirror group (G3) also meets relational expression: at least meet ndp > ndn containing a positive lens and a negative lens, at least meets Vdp < Vdn containing a positive lens and a negative lens; Wherein, ndp is the d line refractive index of described positive lens, and ndn is the d line refractive index of described negative lens, and Vdp is the abbe number of described positive lens, and Vdn is the abbe number of described negative lens.
3. wide visual field high resolving power projection objective as claimed in claim 1, is characterized in that: in the first mirror group (G1): at least meet containing a positive lens and a negative lens: ndp > ndn; At least meet containing a positive lens and a negative lens: Vdp < Vdn.
4. wide visual field high resolving power projection objective as claimed in claim 1, is characterized in that: 4< β <18.
5. as the wide visual field high resolving power projection objective in Claims 1-4 as described in any one, it is characterized in that: the lens total quantity of described wide visual field high resolving power projection objective is between 12 to 28.
6. as the wide visual field high resolving power projection objective in Claims 1-4 as described in any one, it is characterized in that: described equivalent parallel plate is arranged between the first mirror group (G1) and the 3rd mirror group (G3), and described equivalent parallel plate is the divided beams device with fractional transmission and part reflection function.
7. as the wide visual field high resolving power projection objective in Claims 1-4 as described in any one, it is characterized in that: all lens surfaces in the first mirror group (G1), the second mirror group (G2), the 3rd mirror group (G3) are sphere, not containing aspheric surface, the simple lens that the second mirror group (G2), the 3rd mirror group (G3) are not containing cemented surface forms.
8. as the wide visual field high resolving power projection objective in Claims 1-4 as described in any one, it is characterized in that: the second mirror group (G2) comprises at least two lens with negative power and wherein at least one lens is biconcave lens; Also comprise at least three lens with positive light coke and wherein at least two lens are biconvex lens.
9. as the wide visual field high resolving power projection objective in Claims 1-4 as described in any one, it is characterized in that: the 3rd mirror group (G3) comprises at least two lens with negative power; Also comprise at least two lens with positive light coke and comprise at least one crescent lens.
10. as the wide visual field high resolving power projection objective in Claims 1-4 as described in any one, it is characterized in that: the openings of sizes of diaphragm can regulate.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201510184356.XA CN104749752B (en) | 2015-04-17 | 2015-04-17 | A kind of wide visual field high-resolution projection objective |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201510184356.XA CN104749752B (en) | 2015-04-17 | 2015-04-17 | A kind of wide visual field high-resolution projection objective |
Publications (2)
Publication Number | Publication Date |
---|---|
CN104749752A true CN104749752A (en) | 2015-07-01 |
CN104749752B CN104749752B (en) | 2017-10-13 |
Family
ID=53589701
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201510184356.XA Active CN104749752B (en) | 2015-04-17 | 2015-04-17 | A kind of wide visual field high-resolution projection objective |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN104749752B (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN106646885A (en) * | 2016-12-30 | 2017-05-10 | 苏州苏大维格光电科技股份有限公司 | Projection object lens and three dimensional display apparatus |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1289938A (en) * | 1999-09-24 | 2001-04-04 | 松下电器产业株式会社 | Projecting lenses and projector therewith |
US20130050840A1 (en) * | 2011-08-22 | 2013-02-28 | Bae Systems Information And Electronic Systems Integration Inc. | Low distortion athermalized imaging lens |
CN103487921A (en) * | 2013-09-30 | 2014-01-01 | 中国科学院西安光学精密机械研究所 | Optical system of large-visual-field high-resolution three-linear-array stereo aerial surveying camera |
CN104062761A (en) * | 2014-07-17 | 2014-09-24 | 张家港中贺自动化科技有限公司 | Wide spectral line projection optical system and photoetching device |
-
2015
- 2015-04-17 CN CN201510184356.XA patent/CN104749752B/en active Active
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1289938A (en) * | 1999-09-24 | 2001-04-04 | 松下电器产业株式会社 | Projecting lenses and projector therewith |
US20130050840A1 (en) * | 2011-08-22 | 2013-02-28 | Bae Systems Information And Electronic Systems Integration Inc. | Low distortion athermalized imaging lens |
CN103487921A (en) * | 2013-09-30 | 2014-01-01 | 中国科学院西安光学精密机械研究所 | Optical system of large-visual-field high-resolution three-linear-array stereo aerial surveying camera |
CN104062761A (en) * | 2014-07-17 | 2014-09-24 | 张家港中贺自动化科技有限公司 | Wide spectral line projection optical system and photoetching device |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN106646885A (en) * | 2016-12-30 | 2017-05-10 | 苏州苏大维格光电科技股份有限公司 | Projection object lens and three dimensional display apparatus |
CN106646885B (en) * | 2016-12-30 | 2020-02-11 | 苏州苏大维格光电科技股份有限公司 | Projection objective and three-dimensional display device |
Also Published As
Publication number | Publication date |
---|---|
CN104749752B (en) | 2017-10-13 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
JP5277324B2 (en) | Microscope objective lens | |
CN104297906A (en) | Optical lens | |
CN108318995B (en) | Lens system and lens | |
CN110412720B (en) | Optical lens | |
JP2013092774A (en) | Lens system | |
CN109143555B (en) | Zoom lens | |
CN112859299A (en) | Fixed focus lens | |
CN110320637B (en) | Lens and method for manufacturing the same | |
CN108267845B (en) | Athermalized large-aperture objective optical system | |
CN111538148B (en) | Small-magnification camera and small-magnification zoom lens | |
CN104730688A (en) | Wide-visual-field and high-resolution optical system | |
CN104749745A (en) | Large-visual-field high-resolution optical system | |
CN104749746A (en) | Wide-spectrum and large-view field projection objective lens | |
CN104730693B (en) | Wide-spectrum and large-visual-field projection objective lens | |
CN115097612B (en) | Fixed focus lens | |
CN208110148U (en) | A kind of large aperture ultra-wide angle imaging system | |
JP7149550B1 (en) | Imaging optical system | |
CN109425963B (en) | Optical lens | |
CN216013795U (en) | Fixed focus lens | |
CN104749752A (en) | Wide-view-field and high-resolution projection objective lens | |
CN104730697B (en) | Wide-visual-field and high-resolution projection lens | |
CN214845994U (en) | Fixed focus lens | |
CN211236416U (en) | Fatigue monitoring lens | |
CN108614345B (en) | Six-piece type microscope lens group | |
CN213581568U (en) | Fixed focus lens |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C06 | Publication | ||
PB01 | Publication | ||
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
GR01 | Patent grant | ||
GR01 | Patent grant |