CN102016682A - Imaging optical system - Google Patents

Imaging optical system Download PDF

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Publication number
CN102016682A
CN102016682A CN2009800005873A CN200980000587A CN102016682A CN 102016682 A CN102016682 A CN 102016682A CN 2009800005873 A CN2009800005873 A CN 2009800005873A CN 200980000587 A CN200980000587 A CN 200980000587A CN 102016682 A CN102016682 A CN 102016682A
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China
Prior art keywords
lens
optical system
face
expression
imaging optical
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金井纪文
约耳·科维尔
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Nalux Co Ltd
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Nalux Co Ltd
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    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B13/00Optical objectives specially designed for the purposes specified below
    • G02B13/18Optical objectives specially designed for the purposes specified below with lenses having one or more non-spherical faces, e.g. for reducing geometrical aberration
    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B5/00Optical elements other than lenses
    • G02B5/18Diffraction gratings
    • G02B5/1876Diffractive Fresnel lenses; Zone plates; Kinoforms
    • G02B5/189Structurally combined with optical elements not having diffractive power

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
  • Lenses (AREA)
  • Diffracting Gratings Or Hologram Optical Elements (AREA)

Abstract

Provided is an imaging optical system which comprises, sequentially from the object side to the image surface side, a first lens having a positive power, a second lens which is a meniscus lens having a convex surface on the image side, a third lens having a positive power, and a fourth lens having a negative power. The power of the third lens in the vicinity of the principal ray in the meridional direction is positive in the paraxial area, and is negative in an area distant from the optical axis. The power of the fourth lens in the vicinity of the principal ray in the meridional direction is negative in the paraxial area, and is positive in an area distant from the optical axis. The first lens is provided with diffraction gratings on the image side surface. If it is assumed that the focal length of the second lens is f2, the resultant focal length of the imaging optical system is fT, and the distance between the aperture stop or the apex of the object side surface of the first lens, whichever is closer to the object side, and the image surface is TTL, the following formulae are satisfied; |f 2 /f T | >= 3 (1) TTL/f T <= 1.2 (2).

Description

Imaging optical system
Technical field
The present invention relates to the imaging optical system of use in digital camera, the mobile phone of being with camera function, scanner etc.
Background technology
Requirement at the camera head of HIGH RESOLUTION is strong further.Therefore, for the imaging optical system that in this camera head, uses, also require miniaturization and higher resolution.This imaging optical system is is for example recorded and narrated in patent documentation 1~3 grade.
As the means that make the imaging optical system miniaturization, there is the trend of the method that adopts wide-angleization recently morely.In solid-state imager, for light is suppressed to Min. by blocking of the wall of wiring layer, need the incident angle of restriction light, and, need to force angle to be controlled in the predetermined angular range light corresponding to wide-angleization to imaging apparatus.General in the small-sized image pickup optical system that constitutes by 4, the 2nd lens that utilization has negative power carry out the correction of a last chromatic aberation, simultaneously significantly change the direction of light, and utilize the 4th lens control light to make it less to the incident angle of imaging apparatus towards maximum image height.But, in this method, have the relatively strictness of tolerance of the 2nd lens of bigger negative power, if surpass the scope of tolerance, then along with produce bigger aberration near maximum field of view, the result causes the deterioration of picture.
In order to make the optical system of this tolerance strictness, processing and assembling spended time are only causing decrease in yield to passing through after making under the situation of optical system as product that inspection is regarded as certified products.Which kind of situation no matter, the result causes the manufacturing cost of imaging optical system to rise.
On the other hand, at present by exploitation CMOS (Complementally Metal OxideSemiconductor: the back side illuminaton technology of imaging sensor (Backside illumination:BSI) complementary metal oxide semiconductor (CMOS)), light enlarges to the permission incident angle of sensor, but the work of designing and developing that the advantage of the advantage of this technology when making brought into play, also being in not have the state that makes progress.
Existing technical literature
Patent documentation 1: No. 3424030 communiques of Jap.P.
Patent documentation 2: No. 4032667 communiques of Jap.P.
Patent documentation 3: No. 4032668 communiques of Jap.P.
Therefore, small-sized, the high resolving power and the imaging optical system that can suppress manufacturing cost had demand.
Summary of the invention
Imaging optical system of the present invention plays the image planes side from object side and is provided with: the 1st lens with positive light coke; Protruding meniscus lens to the picture side is the 2nd lens; The 3rd lens with positive light coke; And the 4th lens with negative power.For near the focal power the chief ray on the meridian direction of the 3rd lens, have near axis area for just, be negative zone away from the position of optical axis.For near the focal power the chief ray on the meridian direction of the 4th lens, have near axis area for negative, be positive zone in position away from optical axis.The 1st lens have diffraction grating as the side.At the focal length of establishing the 2nd lens is f 2, the synthetic focal length that is set as image optical system is f T, a side who establishes object side from the summit of the object side of aperture face or the 1st lens satisfies following condition when the distance of image planes is TTL
(several 1)
|f 2/f T|≥3 (1)
TTL/f T≤1.2 (2)。
According to the present invention, utilize the diffraction grating of the image planes side of being located at the 1st lens to carry out the correction (colour killing) of a last chromatic aberation, reduce the absolute value of the 2nd power of lens thus, so that satisfy formula (1).Therefore, can enlarge the assembling tolerance, reduce manufacturing cost.
And, according to the present invention, satisfy formula (2) by constituting, can realize compact imaging optical system.
According to the embodiment of the present invention, be f at the focal length of establishing the 4th lens 4, the d line refractive index of establishing the material of the 4th lens is n 4The time, satisfy following condition
(several 2)
-1.1≤(n 4f 4)/f T≤-0.65 (3)。
According to present embodiment, satisfy formula (3) by constituting, Po Zi cuts down (Petzval) and diminishes, and can be implemented near the less imaging optical system of the curvature of the image optical axis, can control the variation of the curvature of the image till higher image height position smoothly and gently.
According to the embodiment of the present invention, diffraction grating is made of endless belt, and the endless belt number is below 10.
According to present embodiment, because the endless belt number is below 10, so the veiling glare that derives from other times light (flare) that the processing limit is caused and the influence of ghost image (ghost) can be suppressed to Min..
Description of drawings
Fig. 1 is the figure of structure of the imaging optical system of expression embodiment 1.
Fig. 2 is the figure of aberration of the imaging optical system of expression embodiment 1.
Fig. 3 is the figure of structure of the imaging optical system of expression embodiment 2.
Fig. 4 is the figure of aberration of the imaging optical system of expression embodiment 2.
Fig. 5 is the figure of structure of the imaging optical system of expression embodiment 3.
Fig. 6 is the figure of aberration of the imaging optical system of expression embodiment 3.
Fig. 7 is the figure of structure of the imaging optical system of expression embodiment 4.
Fig. 8 is the figure of aberration of the imaging optical system of expression embodiment 4.
Fig. 9 is the figure of structure of the imaging optical system of expression embodiment 5.
Figure 10 is the figure of aberration of the imaging optical system of expression embodiment 5.
Figure 11 is the figure of structure of the imaging optical system of expression embodiment 6.
Figure 12 is the figure of aberration of the imaging optical system of expression embodiment 6.
Embodiment
Fig. 1 is the figure of structure of the imaging optical system of expression an embodiment of the invention.The imaging optical system of present embodiment plays as side from object side and is provided with the 1st lens the 101, the 2nd lens the 102, the 3rd lens 103 and the 4th lens 104.Aperture is compared the face of picture side of the 1st lens 101 near object side, and the summit of face of object side of comparing the 1st lens 101 is near the picture side.Specifically, aperture is positioned on the face of object side of the 1st lens 101.By the light of the 1st lens the 101, the 2nd lens the 102, the 3rd lens 103 and the 4th lens 104, arrive image planes 106 by glass plate 105.
Below, the feature of imaging optical system of the present invention is described.Below, establish i and be 1~4 integer, establish the focal length of i lens, the d line of lens material (wavelength 587.6nm) refractive index is respectively
(several 3)
f i、n i
Be set as the synthetic focal length of image optical system and from the summit of the object side of aperture face or the 1st lens one side of object side be respectively to the distance of image planes (below be also referred to as optical length)
(several 4)
f T、TTL。
The type of 4 lens
The imaging optical system of embodiments of the present invention plays the image planes side from object side and is provided with: the 1st lens with positive light coke; Protruding meniscus lens to the picture side is the 2nd lens; The 3rd lens with positive light coke; With the 4th lens with negative power.Wherein, lens have the plus or minus focal power, are meant that lens have the plus or minus focal power near it is paraxial.
Near the chief ray on the meridian direction of the 3rd lens focal power has near axis area for just, be negative zone in the position away from optical axis.Near the chief ray on the meridian direction of the 4th lens focal power, have near axis area for negative, be positive zone in position away from optical axis.By the 3rd lens and the 4th lens that combination has above-mentioned focal power respectively, can control that to become the curvature of the image that makes from the near axis area to the maximum field of view less.
Diffraction grating
The imaging optical system of embodiments of the present invention is used for revising the endless belt diffraction grating of chromatic aberation on the axle (below be also referred to as colour killing) having as the side of the 1st lens.The endless belt number is below 10.If the endless belt number is greater than 10, then the width of the endless belt of circumference diminishes, and the influence of the processing veiling glare that derives from other times light that causes of limit and ghost image is increased.
The absolute value of the focal length of the 2nd lens and the ratio of synthetic focal length
The imaging optical system of embodiments of the present invention satisfies following formula.
(several 5)
|f 2/f T|≥3 (1)。
In in the past and imaging optical system same type of the present invention, difference at the Abbe number (dispersion rate) of the material of utilizing lens is carried out under the situation of colour killing, the 1st lens are made as the lens with positive light coke that are made of low material of disperseing, the 2nd lens are made as the lens with negative power that the material by high dispersive constitutes.In this case, for the colour killing performance that realizes being scheduled to, the negative power that need make the 2nd lens is more than predetermined size.And, using diffraction grating to carry out under the situation of colour killing, in order to improve the performance of colour killing, carry out colour killing in conjunction with the colour killing of the difference of the size of the dispersion that has utilized the lens materials with based on the colour killing of diffraction grating.
According to method in the past, the resolution in the design can access abundant raising.But in fact the machining tolerance of the lens in the manufacture process or assembling tolerance are relatively stricter, make relatively difficulty, perhaps produce the problem that manufacturing cost rises.
Inventors are by analyzing manufacture process, and the result obtains following opinion, and the 1st lens have positive light coke, and the 2nd lens have the predetermined above negative power of size, and this makes the assembling tolerance of these lens become strict.Therefore, as long as can under the state that keeps high-resolution, reduce the negative power of the 2nd lens, just can reduce manufacturing cost.The present invention has realized that according to above-mentioned opinion the negative power that reduces the 2nd lens is to satisfy the imaging optical system of formula (1) under the state that keeps high-resolution.In the present invention, make diffraction grating have main colour killing function, reduce the negative power of the 2nd lens thus.
The ratio of optical length and synthetic focal length
The imaging optical system of embodiments of the present invention satisfies following formula.
(several 6)
TTL/f T≤1.2 (2)
If optical length and synthetic focal length surpass the higher limit of formula (2), then be difficult to realize compact imaging optical system.
The ratio of the d line refractive index of the material of the 4th lens and the product of focal length and synthetic focal length
The imaging optical system of embodiments of the present invention satisfies following formula.
(several 7)
-1.1≤(n 4f 4)/f T≤-0.65 (3)
Generally, for the curvature of the image of the imaging optical system that reduces to constitute by a plurality of lens, the Po Zi that utilizes following formula to represent is cut down and P near zero.
(several 8)
P = &Sigma; i = 1 m 1 n 1 f i - - - ( 4 )
In the present embodiment, the 1st and the 3rd lens have positive light coke, and the absolute value of the 2nd power of lens is less, so only the 4th lens have substantial negative power.Therefore, cut down for the Po Zi that makes formula (4) and, need satisfy formula (3) near zero.
Below, embodiments of the invention 1~6 are described.
The feature of the imaging wire system of embodiment
Table 1 is the table of the feature of expression embodiment 1~6.In the table below, except other had record, the unit of length was a millimeter.
(table 1)
Embodiment |f 2/f T| TTL/f T (n 4f 4)/f T The endless belt number
1 -50.00 1.19 -0.858 10
2 -6.23 1.14 -0.866 9
3 -3.47 1.20 -1.092 10
4 -3.97 1.17 -0.765 8
5 -3.59 1.15 -0.782 5
6 6.85 1.15 -0.685 9
According to table 1, embodiment 1~6 satisfies formula (1)~formula (3).And the endless belt number of diffraction grating of being located at the image planes side of the 1st lens is below 10.
The formula of the lens face of expression embodiment and the phase function of diffraction grating
The face of each lens of embodiment utilizes following formula to represent.
(several 9)
z = r 2 / R 1 + 1 - ( 1 + k ) ( r / R ) 2 + &Sigma; i = 4 , ieven 16 A i r i - - - ( 5 )
Wherein, z is illustrated in the intersection point of lens face and optical axis as benchmark, be made as the coordinate of some timing, on the lens face in the position of optical axis direction as side.R represents that point on the lens face is apart from the distance of optical axis.R represents the radius-of-curvature on the summit of lens face.K represents the constant of the cone.Ai represents polynomial coefficient.
The phase function of diffraction grating of being located at the image planes side of the 1st lens utilizes following formula to represent.
(several 10)
&Phi; = &Sigma; i = 2 , ieven 16 B i r i - - - ( 6 )
Wherein, Bi represents polynomial coefficient.
Embodiment 1
Fig. 1 is the figure of structure of the imaging optical system of expression embodiment 1.The imaging optical system of embodiment 1 plays as side from object side and is provided with the 1st lens the 101, the 2nd lens the 102, the 3rd lens 103 and the 4th lens 104.Aperture is compared the face of picture side of the 1st lens 101 near object side, and the summit of face of object side of comparing the 1st lens 101 is near the picture side.Specifically, aperture is positioned on the face of object side of the 1st lens 101.By the light of the 1st lens the 101, the 2nd lens the 102, the 3rd lens 103 and the 4th lens 104, arrive image planes 106 by glass plate 105.
In the present embodiment, the image planes side at the 1st lens is provided with the diffraction grating that colour killing is used.In the present embodiment, the colour killing function is mainly born by diffraction grating, and the endless belt number of diffraction grating is 10.
Fig. 2 is the figure of aberration of the imaging optical system of expression embodiment 1.Fig. 2 represents the aberration of 3 wavelength of relevant visibility region.Fig. 2 (a) is the figure that expression spherical aberration and axle are gone up chromatic aberation.The transverse axis of Fig. 2 (a) represents with the image planes position to be the focal position (unit is a millimeter) of the optical axis direction of benchmark.The longitudinal axis of Fig. 2 (a) represent in the aperture light pass through the position.The O of the longitudinal axis represents the center of light by aperture, and the maximal value of the longitudinal axis is represented the end of light by aperture.Fig. 2 (b) is the figure of expression astigmatism and curvature of the image.The transverse axis of Fig. 2 (b) is represented the focal position (unit is a millimeter) of optical axis direction.The longitudinal axis of Fig. 2 (b) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.In Fig. 2 (b), T represents the shape of meridianal image surface, and S represents the shape of sagittal image surface.Fig. 2 (c) is the figure of expression distortion aberration.The transverse axis of Fig. 2 (c) aberration (distortion) (unit is a number percent) of representing to distort.The longitudinal axis of Fig. 2 (c) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.
Table 2 is tables of lens data of the imaging optical system of expression embodiment 1.The face of the 1st~8th expression the 1st~the 4th lens, the face of the 9th~10th expression glass plate.In table 2, as example, the face of the 1st (face of the object side of the 1st lens) is the 1st interval with the 2nd (face of the picture side of the 1st lens) at interval.
Table 3 is the radius of curvature R on summit lens face, shown in the formula (5) of the 1st~the 8th of expression and the table of constant of the cone k.
Table 4 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 1st~the 4th of expression.
Table 5 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 5th~the 8th of expression.
Table 6 is the tables of the polynomial coefficient B i shown in the expression (6), the phase function of formula (6) expression diffraction grating.
(table 2)
The face sequence number Face at interval Refractive index Abbe number
1 1.549 1.509398 56.4745
2 797.445
3 -0.969 1.509398 56.4745
4 -1.082
5 -7.722 1.509398 56.4745
6 -1.171
7 -1.391 1.509398 56.4745
8 2.890
9 1.549 1.518800 64.1673
10 797.445
(table 3)
The face sequence number R k
1 1.549 3.262064
2 797.445 0.000000
3 -0.969 -0.595475
4 -1.082 -1.595714
5 -7.722 -0.408716
6 -1.171 -4.041903
7 -1.391 -9.259999
8 2.890 -1.416315
(table 4)
Coefficient The 1st The 2nd The 3rd The 4th
A4 -1.187985e-01 -8.061499e-02 -8.496010e-02 8.001348e-03
A6 -7.020756e-01 -3.374785e-01 6.762746e-01 2.350190e-01
A8 3.525781e+00 9.625311e-01 4.555051e-01 4.250412e-01
A10 -7.329295e+00 -1.250259e+00 -6.538512e-01 1.184556e-01
A12 -2.437049e+01 -1.748054e+00 -7.464657e-01 -4.276392e-01
A14 8.005244e+01 4.250112e-01 1.661744e-01 3.542042e-01
A16 -5.187142e+00 7.034610e+00 -1.685258e+00 2.250833e-01
(table 5)
Coefficient The 5th The 6th The 7th The 8th
A4 1.363439e-01 1.354311e-01 -2.965270e-02 -1.270685e-01
A6 -5.342901e-02 1.914656e-02 -2.583718e-02 2.283744e-02
A8 -1.567813e-03 -9.306951e-3 2.849597e-02 8.260524e-03
A10 -4.686840e-03 -1.023669e-02 9.739307e-03 -7.393002e-03
A12 -4.479816e-3 1.750321e-04 -4.601589e-03 1.723132e-03
A14 1.905349e-02 1.651148e-03 -4.599843e-03 -3.539828e-05
A16 -9.940526e-03 -2.036048e-04 1.638742e-03 -3.376488e-05
(table 6)
B2 B4 B6 B8
-1.528656e+2 4.695117e+1 -2.107326e+2 2.103605e+3
B10 B12 B14 B16
-3.837204e+3 1.104583e+3 -2.661279e+4 4.714037e+4
Embodiment 2
Fig. 3 is the figure of structure of the imaging optical system of expression embodiment 2.The imaging optical system of embodiment 2 plays as side from object side and is provided with the 1st lens the 201, the 2nd lens the 202, the 3rd lens 203 and the 4th lens 204.Aperture is compared the face of picture side of the 1st lens 201 near object side, and the summit of face of object side of comparing the 1st lens 201 is near the picture side.Specifically, aperture is positioned on the face of object side of the 1st lens 201.By the light of the 1st lens the 201, the 2nd lens the 202, the 3rd lens 203 and the 4th lens 204, arrive image planes 206 by glass plate 205.
In the present embodiment, the image planes side at the 1st lens is provided with the diffraction grating that colour killing is used.In the present embodiment, the colour killing function is mainly born by diffraction grating, and the endless belt number of diffraction grating is 9.
Fig. 4 is the figure of aberration of the imaging optical system of expression embodiment 2.Fig. 4 represents the aberration of 3 wavelength of relevant visibility region.Fig. 4 (a) is the figure that expression spherical aberration and axle are gone up chromatic aberation.The transverse axis of Fig. 4 (a) represents with the image planes position to be the focal position (unit is a millimeter) of the optical axis direction of benchmark.The longitudinal axis of Fig. 4 (a) represent in the aperture light pass through the position.The O of the longitudinal axis represents the center of light by aperture, and the maximal value of the longitudinal axis is represented the end of light by aperture.Fig. 4 (b) is the figure of expression astigmatism and curvature of the image.The transverse axis of Fig. 4 (b) is represented the focal position (unit is a millimeter) of optical axis direction.The longitudinal axis of Fig. 4 (b) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.In Fig. 4 (b), T represents the shape of meridianal image surface, and S represents the shape of sagittal image surface.Fig. 4 (c) is the figure of expression distortion aberration.The transverse axis of Fig. 4 (c) aberration (distortion) (unit is a number percent) of representing to distort.The longitudinal axis of Fig. 4 (c) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.
Table 7 is tables of lens data of the imaging optical system of expression embodiment 2.The face of the 1st~8th expression the 1st~the 4th lens, the face of the 9th~10th expression glass plate.In table 7, as example, the face of the 1st (face of the object side of the 1st lens) is the 1st interval with the 2nd (face of the picture side of the 1st lens) at interval.
Table 8 is the radius of curvature R on summit lens face, shown in the formula (5) of the 1st~the 8th of expression and the table of constant of the cone k.
Table 9 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 1st~the 4th of expression.
Table 10 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 5th~the 8th of expression.
Table 11 is the tables of the polynomial coefficient B i shown in the expression (6), the phase function of formula (6) expression diffraction grating.
(table 7)
The face sequence number Face at interval Refractive index Abbe number
1 0.422 1.509398 56.4745
2 0.588
3 0.400 1.509398 56.4745
4 0.624
5 0.504 1.509398 56.4745
6 0.428
7 0.422 1.509398 56.4745
8 0.588
9 0.400 1.509398 56.4745
10 0.624
(table 8)
The face sequence number R k
1 1.322 0.000000
2 2.748 11.259521
3 -4.000 0.000000
4 -6.105 0.000000
5 -6.105 0.000000
6 -1.806 0.000000
7 1.322 0.000000
8 2.748 11.259521
(table 9)
Coefficient The 1st The 2nd The 3rd The 4th
A4 1.747321e-02 0.000000e+00 -3.431316e-01 -3.198195e-01
A6 3.109056e-01 0.000000e+00 9.785284e-01 7.635249e-01
A8 -2.031971e+00 0.000000e+00 -4.412477e+00 -2.569051e+00
A10 8.494980e+00 0.000000e+00 1.277062e+01 5.459113e+00
A12 -1.910079e+01 0.000000e+00 -2.288483e+01 -6.783178e+00
A14 2.269427e+01 0.000000e+00 2.302588e+01 4.592895e+00
A16 -1.079430e+01 0.000000e+00 -9.485529e+00 -1.257927e+00
(table 10)
Coefficient The 5th The 6th The 7th The 8th
A4 -1.32445e-01 7.745301e-02 -2.428937e-02 -1.929806e-01
A6 3.352289e-01 2.093621e-01 1.016031e-01 1.117350e-01
A8 -5.694255e-01 -2.676335e-01 -8.039843e-02 -5.213730e-02
A10 5.356910e-01 1.606422e-01 4.624343e-02 1.603703e-02
A12 -3.070197e-01 -5.425856e-02 -1.646364e-02 -3.101065e-03
A14 9.617333e-02 9.830058e-03 3.115041e-03 3.417470e-04
A16 -1.225905e-02 -7.230575e-04 -2.420231e-04 -1.684328e-05
(table 11)
B2 B4 B6 B8
-9.884395e+1 -1.579645e+0 -4.829148e+2 1.107287e+3
B10 B12 B14 B16
-3.618775e+2 0.000000e+0 0.000000e+0 0.000000e+0
Embodiment 3
Fig. 5 is the figure of structure of the imaging optical system of expression embodiment 3.The imaging optical system of embodiment 3 plays as side from object side and is provided with the 1st lens the 301, the 2nd lens the 302, the 3rd lens 303 and the 4th lens 304.Aperture is compared the face of picture side of the 1st lens 301 near object side, and the summit of face of object side of comparing the 1st lens 301 is near the picture side.Specifically, aperture is positioned on the face of object side of the 1st lens 301.By the light of the 1st lens the 301, the 2nd lens the 302, the 3rd lens 303 and the 4th lens 304, arrive image planes 306 by glass plate 305.
In the present embodiment, the image planes side at the 1st lens is provided with the diffraction grating that colour killing is used.In the present embodiment, the colour killing function is mainly born by diffraction grating, and the endless belt number of diffraction grating is 10.
Fig. 6 is the figure of aberration of the imaging optical system of expression embodiment 3.Fig. 6 represents the aberration of 3 wavelength of relevant visibility region.Fig. 6 (a) is the figure that expression spherical aberration and axle are gone up chromatic aberation.The transverse axis of Fig. 6 (a) represents with the image planes position to be the focal position (unit is a millimeter) of the optical axis direction of benchmark.The longitudinal axis of Fig. 6 (a) represent in the aperture light pass through the position.The O of the longitudinal axis represents the center of light by aperture, and the maximal value of the longitudinal axis is represented the end of light by aperture.Fig. 6 (b) is the figure of expression astigmatism and curvature of the image.The transverse axis of Fig. 6 (b) is represented the focal position (unit is a millimeter) of optical axis direction.The longitudinal axis of Fig. 6 (b) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.In Fig. 6 (b), T represents the shape of meridianal image surface, and S represents the shape of sagittal image surface.Fig. 6 (c) is the figure of expression distortion aberration.The transverse axis of Fig. 6 (c) aberration (distortion) (unit is a number percent) of representing to distort.The longitudinal axis of Fig. 6 (c) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.
Table 12 is tables of lens data of the imaging optical system of expression embodiment 3.The face of the 1st~8th expression the 1st~the 4th lens, the face of the 9th~10th expression glass plate.In table 12, as example, the face of the 1st (face of the object side of the 1st lens) is the 1st interval with the 2nd (face of the picture side of the 1st lens) at interval.
Table 13 is the radius of curvature R on summit lens face, shown in the formula (5) of the 1st~the 8th of expression and the table of constant of the cone k.
Table 14 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 1st~the 4th of expression.
Table 15 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 5th~the 8th of expression.
Table 16 is the tables of the polynomial coefficient B i shown in the expression (6), the phase function of formula (6) expression diffraction grating.
(table 12)
The face sequence number Face at interval Refractive index Abbe number
1 0.425 1.509398 56.4745
2 0.486
3 0.300 1.509398 56.4745
4 0.249
5 0.499 1.509398 56.4745
6 0.179
7 0.225 1.509398 56.4745
8 0.161
9 0.400 1.516800 64.1673
10 0.600
(table 13)
The face sequence number R k
1 0.961 0.000000
2 2.203 13.323319
3 -1.103 0.000000
4 -1.528 0.000000
5 7.695 0.000000
6 -1.286 0.000000
7 -2.998 0.000000
8 1.724 0.000000
(table 14)
Coefficient The 1st The 2nd The 3rd The 4th
A4 -3.895054e-02 0.000000e+00 -1.127108e+00 -1.690591e+00
A6 3.231423e+00 0.000000e+00 6.826806e+00 7.605403e+00
A8 -4.048473e+01 0.000000e+00 -4.433775e+01 -2.807306e+01
A10 2.895483e+02 0.000000e+00 2.070730e+02 7.695809e+01
A12 -1.140922e+03 0.000000e+00 -5.508641e+02 -1.175100e+02
A14 2.349160e+03 0.000000e+00 7.944282e+02 8.112386e+01
A16 -1.957247e+03 0.000000e+00 -5.045481e+02 -2.831296e+01
(table 15)
The 5th of coefficient The 6th The 7th The 8th
A4 -1.595235e+00 -5.022323e-01 -4.352005e-01 -4.690895e-01
A6 3.315832e+00 1.418148e+00 1.412097e+00 4.130183e-01
A8 -3.468924e+00 -1.455882e+00 -2.111821e+00 -2.964520e-01
A10 2.373072e+00 1.106380e+00 1.819399e+00 1.184345e-02
A12 -1.283123e+00 -5.772771e-01 -9.073987e-01 -1.892968e-02
A14 4.633910e-01 1.404333e-01 2.411165e-01 -1.982838e-03
A16 -6.391510e-02 -1.428193e-03 -2.624000e-02 7.085923e-04
(table 16)
B2 B4 B6 B8
-2.032752e+2 7.561459e+2 -8.571489e+3 3.924981e+4
B10 B12 B14 B16
-6.538037e+4 0.000000e+0 0.000000e+0 0.000000e+0
Embodiment 4
Fig. 7 is the figure of structure of the imaging optical system of expression embodiment 4.The imaging optical system of embodiment 4 plays as side from object side and is provided with the 1st lens the 401, the 2nd lens the 402, the 3rd lens 403 and the 4th lens 404.Aperture is compared the face of picture side of the 1st lens 401 near object side, and the summit of face of object side of comparing the 1st lens 401 is near the picture side.Specifically, aperture is positioned on the face of object side of the 1st lens 401.By the light of the 1st lens the 401, the 2nd lens the 402, the 3rd lens 403 and the 4th lens 404, arrive image planes 406 by glass plate 405.
In the present embodiment, the image planes side at the 1st lens is provided with the diffraction grating that colour killing is used.In the present embodiment, the colour killing function is mainly born by diffraction grating, and the endless belt number of diffraction grating is 8.
Fig. 8 is the figure of aberration of the imaging optical system of expression embodiment 4.Fig. 8 represents the aberration of 3 wavelength of relevant visibility region.Fig. 8 (a) is the figure that expression spherical aberration and axle are gone up chromatic aberation.The transverse axis of Fig. 8 (a) represents with the image planes position to be the focal position (unit is a millimeter) of the optical axis direction of benchmark.The longitudinal axis of Fig. 8 (a) represent in the aperture light pass through the position.The O of the longitudinal axis represents the center of light by aperture, and the maximal value of the longitudinal axis is represented the end of light by aperture.Fig. 8 (b) is the figure of expression astigmatism and curvature of the image.The transverse axis of Fig. 8 (b) is represented the focal position (unit is a millimeter) of optical axis direction.The longitudinal axis of Fig. 8 (b) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.In Fig. 8 (b), T represents the shape of meridianal image surface, and S represents the shape of sagittal image surface.Fig. 8 (c) is the figure of expression distortion aberration.The transverse axis of Fig. 8 (c) aberration (distortion) (unit is a number percent) of representing to distort.The longitudinal axis of Fig. 8 (c) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.
Table 17 is tables of lens data of the imaging optical system of expression embodiment 4.The face of the 1st~8th expression the 1st~the 4th lens, the face of the 9th~10th expression glass plate.In table 17, as example, the face of the 1st (face of the object side of the 1st lens) is the 1st interval with the 2nd (face of the picture side of the 1st lens) at interval.
Table 18 is the radius of curvature R on summit lens face, shown in the formula (5) of the 1st~the 8th of expression and the table of constant of the cone k.
Table 19 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 1st~the 4th of expression.
Table 20 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 5th~the 8th of expression.
Table 21 is the tables of the polynomial coefficient B i shown in the expression (6), the phase function of formula (6) expression diffraction grating.
(table 17)
The face sequence number Face at interval Refractive index Abbe number
1 0.506 1.509398 56.4745
2 0.510
3 0.448 1.509398 56.4745
4 0.567
5 0.600 1.509398 56.4745
6 0.323
7 0.424 1.509398 56.4745
8 0.361
9 0.200 1.516800 64.1673
10 0.500
(table 18)
The face sequence number R k
1 1.615 0.000000
2 5.990 0.000000
3 -5.545 0.000000
4 -20.146 0.000000
5 4.894 0.000000
6 -1.645 0.000000
7 -1.809 0.000000
8 2.315 0.000000
(table 19)
Coefficient The 1st The 2nd The 3rd The 4th
A4 -1.749023e-02 -9.565256e-02 -3.030104e-01 -2.339727e-01
A6 1.379234e-02 3.172706e-01 6.439454e-01 1.439101e-01
A8 -1.810620e-01 -1.364540e+00 -2.145083e+00 2.066482e-01
A10 3.918267e-01 2.341339e+00 4.397549e+00 -1.088324e+00
A12 -5.768900e-03 -3.380789e-01 -4.679248e+00 1.975262e+00
A14 -1.403365e+00 -3.795965e+00 2.360303e+00 -1.521156e+00
A16 1.471423e+00 2.669086e+00 -3.965915e-01 4.373559e-01
(table 20)
Coefficient The 5th The 6th The 7th The 8th
A4 -6.359608e-02 2.296205e-01 1.522537e-01 -1.556694e-01
A6 5.095009e-02 -5.461417e-02 -1.594477e-01 5.667338e-02
A8 -6.837353e-02 -1.037771e-02 1.161665e-01 -2.036376e-02
A10 2.212926e-02 1.508685e-02 -1.646901e-02 6.288470e-03
A12 -1.547672e-02 -3.414524e-03 -1.483771e-02 -1.442594e-03
A14 1.757817e-02 -5.156925e-04 6.346313e-03 1.775222e-04
A16 -5.530454e-03 2.562511e-04 -7.190730e-04 -8.615771e-06
(table 21)
B2 B4 B6 B8
-1.176405e+2 1.570718e+2 -1.014214e+3 2.441291e+3
B10 B12 B14 B16
-1.442269e+2 -8.393507e+3 9.855701e+3 8.799554e+2
Embodiment 5
Fig. 9 is the figure of structure of the imaging optical system of expression embodiment 5.The imaging optical system of embodiment 5 plays as side from object side and is provided with the 1st lens the 501, the 2nd lens the 502, the 3rd lens 503 and the 4th lens 504.Aperture is compared the face of picture side of the 1st lens 501 near object side, and the summit of face of object side of comparing the 1st lens 501 is near the picture side.Specifically, aperture is positioned on the face of object side of the 1st lens 501.By the light of the 1st lens the 501, the 2nd lens the 502, the 3rd lens 503 and the 4th lens 504, arrive image planes 506 by glass plate 505.
In the present embodiment, the image planes side at the 1st lens is provided with the diffraction grating that colour killing is used.In the present embodiment, the colour killing function is mainly born by diffraction grating, and the endless belt number of diffraction grating is 5.
Figure 10 is the figure of aberration of the imaging optical system of expression embodiment 5.Figure 10 represents the aberration of 3 wavelength of relevant visibility region.Figure 10 (a) is the figure that expression spherical aberration and axle are gone up chromatic aberation.The transverse axis of Figure 10 (a) represents with the image planes position to be the focal position (unit is a millimeter) of the optical axis direction of benchmark.The longitudinal axis of Figure 10 (a) represent in the aperture light pass through the position.The O of the longitudinal axis represents the center of light by aperture, and the maximal value of the longitudinal axis is represented the end of light by aperture.Figure 10 (b) is the figure of expression astigmatism and curvature of the image.The transverse axis of Figure 10 (b) is represented the focal position (unit is a millimeter) of optical axis direction.The longitudinal axis of Figure 10 (b) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.In Figure 10 (b), T represents the shape of meridianal image surface, and S represents the shape of sagittal image surface.Figure 10 (c) is the figure of expression distortion aberration.The transverse axis of Figure 10 (c) aberration (distortion) (unit is a number percent) of representing to distort.The longitudinal axis of Figure 10 (c) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.
Table 22 is tables of lens data of the imaging optical system of expression embodiment 5.The face of the 1st~8th expression the 1st~the 4th lens, the face of the 9th~10th expression glass plate.In table 22, as example, the face of the 1st (face of the object side of the 1st lens) is the 1st interval with the 2nd (face of the picture side of the 1st lens) at interval.
Table 23 is the radius of curvature R on summit lens face, shown in the formula (5) of the 1st~the 8th of expression and the table of constant of the cone k.
Table 24 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 1st~the 4th of expression.
Table 25 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 5th~the 8th of expression.
Table 26 is the tables of the polynomial coefficient B i shown in the expression (6), the phase function of formula (6) expression diffraction grating.
(table 22)
The face sequence number Face at interval Refractive index Abbe number
1 0.563 1.509398 56.4745
2 0.378
3 0.427 1.606697 26.6056
4 0.660
5 0.521 1.509398 56.4745
6 0.366
7 0.452 1.509398 56.4745
8 0.244
9 0.200 1.516800 64.1673
10 0.500
(table 23)
The face sequence number R k
1 1.382 0.000000
2 5.044 0.000000
3 -2.766 0.000000
4 -4.401 0.000000
5 14.061 0.000000
8 -1.549 0.000000
7 -1.790 0.000000
8 2.401 0.000000
(table 24)
Coefficient The 1st The 2nd The 3rd The 4th
A4 -2.855646e-03 -1.043311e-01 -2.808041e-01 -1.344048e-01
A6 1.704876e-02 2.415598e-01 5.090103e-01 7.171920e-02
A8 -1.870320e-01 -1.384994e+00 -2.180231e+00 2.487732e-01
A10 3.511643e-01 2.230959e+00 4.534381e+00 -1.012351e+00
A12 2.895494e-02 -4.437992e-01 -4.541400e+00 1.977543e+00
A14 -1.062268e+00 -3.556174e+00 2.111603e+00 -1.576140e+00
A16 7.638291e-01 2.351439e+00 -8.413208e-01 4.640379e+00
(table 25)
Coefficient The 5th The 6th The 7th The 8th
A4 -4.354766e-02 1.974514e-01 1.282449e-01 -1.498328e-01
A6 2.397320e-02 -7.318788e-02 -1.587230e-01 5.500940e-02
A8 -6.469818e-02 -4.168990e-03 1.166909e-01 -1.994286e-02
A10 2.507676e-02 1.681294e-02 -1.610335e-02 6.264507e-03
A12 -1.507291e-02 -3.111908e-03 -1.482717e-02 -1.438613e-03
A14 1.747337e-02 -4.857681e-04 6.324777e-03 1.789343e-04
A16 -5.485403e-03 2.261922e-04 -7.172537e-04 -8.954985e-06
(table 26)
B2 B4 B6 B8
-9.990713e+1 1.582908e+2 -1.005374e+3 2.837651e+3
B10 B12 B14 B16
-6.923681e+2 -8.834571e+3 1.261488e+4 -2.041206e+3
Embodiment 6
Figure 11 is the figure of structure of the imaging optical system of expression embodiment 6.The imaging optical system of embodiment 6 plays as side from object side and is provided with the 1st lens the 601, the 2nd lens the 602, the 3rd lens 603 and the 4th lens 604.Aperture is compared the face of picture side of the 1st lens 601 near object side, and the summit of face of object side of comparing the 1st lens 601 is near the picture side.Specifically, aperture is positioned on the face of object side of the 1st lens 601.By the light of the 1st lens the 601, the 2nd lens the 602, the 3rd lens 603 and the 4th lens 604, arrive image planes 606 by glass plate 605.
In the present embodiment, the image planes side at the 1st lens is provided with the diffraction grating that colour killing is used.In the present embodiment, the colour killing function is mainly born by diffraction grating, and the endless belt number of diffraction grating is 9.
Figure 12 is the figure of aberration of the imaging optical system of expression embodiment 6.Figure 12 represents the aberration of 3 wavelength of relevant visibility region.Figure 12 (a) is the figure that expression spherical aberration and axle are gone up chromatic aberation.The transverse axis of Figure 12 (a) represents with the image planes position to be the focal position (unit is a millimeter) of the optical axis direction of benchmark.The longitudinal axis of Figure 12 (a) represent in the aperture light pass through the position.The O of the longitudinal axis represents the center of light by aperture, and the maximal value of the longitudinal axis is represented the end of light by aperture.Figure 12 (b) is the figure of expression astigmatism and curvature of the image.The transverse axis of Figure 12 (b) is represented the focal position (unit is a millimeter) of optical axis direction.The longitudinal axis of Figure 12 (b) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.In Figure 12 (b), T represents the shape of meridianal image surface, and S represents the shape of sagittal image surface.Figure 12 (c) is the figure of expression distortion aberration.The transverse axis of Figure 12 (c) aberration (distortion) (unit is a number percent) of representing to distort.The longitudinal axis of Figure 12 (c) is represented the visual field.The O of the longitudinal axis represents 0 ° of field angle, and the maximal value of the longitudinal axis is represented the maximum field of view angle.
Table 27 is tables of lens data of the imaging optical system of expression embodiment 6.The face of the 1st~8th expression the 1st~the 4th lens, the face of the 9th~10th expression glass plate.In table 27, as example, the face of the 1st (face of the object side of the 1st lens) is the 1st interval with the 2nd (face of the picture side of the 1st lens) at interval.
Table 28 is the radius of curvature R on summit lens face, shown in the formula (5) of the 1st~the 8th of expression and the table of constant of the cone k.
Table 29 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 1st~the 4th of expression.
Table 30 is tables of polynomial coefficient Ai lens face, shown in the formula (5) of the 5th~the 8th of expression.
Table 31 is the tables of the polynomial coefficient B i shown in the expression (6), the phase function of formula (6) expression diffraction grating.
(table 27)
The face sequence number Face at interval Refractive index Abbe number
1 0.527 1.509398 56.4745
2 0.254
3 0.403 1.509398 56.4745
4 0.646
5 0.618 1.509398 56.4745
6 0.618
7 0.437 1.509398 56.4745
8 0.162
9 0.200 1.516800 64.1673
10 0.500
(table 28)
The face sequence number R k
1 1.343 0.142921
2 2.691 0.000000
3 -8.600 0.000000
4 -5.197 0.000000
5 -63.245 0.000000
6 -1.140 -1.702017
7 -1.089 -1.216917
8 3.986 0.425434
(table 29)
Coefficient The 1st The 2nd The 3rd The 4th
A4 8.332022e-03 -1.389558e-01 -2.274908e-01 -1.539207e-01
A8 -3.538307e-02 1.124603e+00 5.547712e-01 3.418851e-01
A8 9.2728569e-1 -1.032517e+01 -3.315306e+00 -1.343115e+00
A10 -6.514877e+00 4.809146e+01 1.196598e+01 3.102905e+00
A12 2.101493e+01 -1.245610e+02 -2.819797e+01 -4.083115e+00
A14 -3.212270e+01 1.860131e+02 3.680839e+01 3.103897e+00
A16 1.923615e+01 -9.078432e+01 -1.907621e+01 -8.667793e-01
(table 30)
Coefficient The 5th The 6th The 7th The 8th
A4 -1.351511e-01 5.367639e-03 1.283405e-01 -7.118472e-02
A8 3.997239e-01 3.527775e-01 5.671902e-02 1.167859e-02
A8 -9.615622e-01 -6.997795e-01 -2.991179e-01 -1.462778e-03
A10 1.348884e++0000 7.965443e-01 3.709253e-01 -2.279567e-05
A12 -1.125343e+00 -5.467434e-01 -2.298936e-02 7.404934e-06
A14 4.737493e-01 1.958755e-01 7.137083e-02 2.809311e-06
A16 -7.598720e-02 -2.797237e-02 -8.867668e-03 -5.853834e-07
(table 31)
B2 B4 B6 B8
-1.286509e+2 1.339627e+2 -6.235052e+2 3.430158e+2
B10 B12 B14 B16
1.680693e+3 -1.163563e+3 8.825705e+3 1.674027e+4

Claims (3)

1. an imaging optical system plays the image planes side from object side and is provided with: the 1st lens with positive light coke; Protruding meniscus lens to the picture side is the 2nd lens; The 3rd lens with positive light coke; And the 4th lens with negative power, wherein,
For near the focal power the chief ray on the meridian direction of the 3rd lens, have near axis area and just be, be negative zone in position away from optical axis, for near the focal power the chief ray on the meridian direction of the 4th lens, have near axis area for negative, be positive zone in position away from optical axis, the 1st lens have diffraction grating as the side, are f at the focal length of establishing the 2nd lens 2, the synthetic focal length that is set as image optical system is f T, a side who establishes object side from the summit of the object side of aperture face or the 1st lens satisfies following condition when the distance of image planes is TTL
|f 2/f T|≥3 (1)
TTL/f T≤1.2 (2)。
2. imaging optical system according to claim 1 wherein, is f at the focal length of establishing described the 4th lens 4, the d line refractive index of establishing the material of described the 4th lens is n 4The time, satisfy following condition
-1.1≤(n 4f 4)/f T≤-0.65 (3)。
3. imaging optical system according to claim 1 and 2, wherein, described diffraction grating is made of endless belt, and the endless belt number is below 10.
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Publication number Priority date Publication date Assignee Title
CN101950064A (en) * 2009-07-08 2011-01-19 纳卢克斯株式会社 Imaging optical system
CN101950064B (en) * 2009-07-08 2012-07-25 纳卢克斯株式会社 Imaging optical system
CN102843510A (en) * 2011-06-14 2012-12-26 宾得理光映像有限公司 Imaging device and distance information detecting method
CN103185958A (en) * 2012-12-28 2013-07-03 玉晶光电(厦门)有限公司 Portable electronic device and optical imaging lens thereof

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