CN205049802U - Ultra wide -angle lens - Google Patents

Abstract

The utility model discloses an ultra wide -angle lens, it is included by thing side to picture side in proper order: have the first lens of negative refracting power, the picture side of these first lens is the concave surface, have the second lens of positive refracting power, the thing side of these second lens is the convex surface, have the third lens of positive refracting power, the picture side of these third lens is the convex surface, the fourth lens that have negative refracting power, have the 5th lens of positive refracting power, the picture side of the 5th lens is the convex surface, the VI lenses who has negative refracting power, this ultra wide -angle lens satisfies following relational expression: - 2.0< F1f< - 1.0, wherein, f1 is the effective focal length of these first lens, and f is this ultra wide -angle lens's effective focal length. Satisfy the ultra wide -angle lens of above -mentioned configuration, can appropriate allocation lens shape and focal power, when realizing super wide angle, be favorable to revising all kinds of aberrations, promote the formation of image quality to guarantee the miniaturization of camera lens.

Description

Bugeye lens

Technical field

The utility model relates to a kind of camera technique field, particularly relates to a kind of slim bugeye lens.

Background technology

Along with the development of science and technology, portable type electronic product progressively rises, the portable type electronic product particularly with camera function obtains people more to be favored, the photo-sensitive cell of general optical system is nothing more than being photosensitive coupling element (CCD) or Complimentary Metal-Oxide semiconductor element (CMOS) two kinds, along with progressing greatly of manufacture of semiconductor technology, the Pixel Dimensions of photo-sensitive cell reduces, and optical system trends towards higher pixel, more high imaging quality.

In order to meet this trend, also high picture element, miniaturization and wide angle are required further for the pick-up lens be mounted on the camera heads such as mobile phone, digital camera, automobile, supervision.In order to realize ultra-wide angle, lens number is easy to increase, and is unfavorable for miniaturization and the lightweight of camera lens; The each aberration of reduction is limited to some extent simultaneously, be unfavorable for improving image quality.

Utility model content

The utility model embodiment is intended at least to solve one of technical matters existed in prior art.For this reason, the utility model embodiment needs to provide a kind of bugeye lens.

A kind of bugeye lens, comprised successively to image side by thing side: first lens with negative refracting power, the face, image side of these the first lens is concave surface; Have the second lens of positive refracting power, the thing side of these the second lens is convex surface; Have the 3rd lens of positive refracting power, the face, image side of the 3rd lens is convex surface; There are the 4th lens of negative refracting power; Have the 5th lens of positive refracting power, the face, image side of the 5th lens is convex surface; There are the 6th lens of negative refracting power; This bugeye lens meets following relationship :-2.0<f1/f<-1.0;

Wherein, f1 is the effective focal length of these the first lens, and f is the effective focal length of this bugeye lens.

Meet the bugeye lens of above-mentioned configuration, can reasonable disposition lens shape and focal power, while realizing ultra-wide angle, be conducive to revising all kinds of aberration, promote image quality, and ensure the miniaturization of camera lens.

In one embodiment, this bugeye lens meets following relationship: 1.3<f45/f<2.0;

Wherein, f45 is the synthesis focal length of the 4th lens and the 5th lens.

In one embodiment, this bugeye lens meets following relationship :-1.0<f1/f2<-0.2;

Wherein, f2 is the effective focal length of these the second lens.

In one embodiment, this bugeye lens meets following relationship: 0.5<R2/R3<0.9;

Wherein, R2 is the radius-of-curvature in the face, image side of these the first lens; R3 is the radius-of-curvature of the thing side of these the second lens.

In one embodiment, this bugeye lens meets following relationship: 1.0<DT11/DT62<1.5;

Wherein, DT11 is the effective radius of the thing side of these the first lens, and DT62 is the effective radius in the face, image side of the 6th lens.

In one embodiment, this bugeye lens meets following relationship: 0.8<f3/f5<2.0; 0.3<f4/f6<2.0;

Wherein, f3 is the effective focal length of the 3rd lens, and f5 is the effective focal length of the 5th lens, and f4 is the effective focal length of the 4th lens, and f6 is the effective focal length of the 6th lens.

In one embodiment, this bugeye lens meets following relationship: 0.2mm ^-1<tan (HFOV)/TTL<0.5mm ^-1;

Wherein, HFOV is the half at the maximum field of view angle of this bugeye lens, and TTL is that the thing side of these the first lens is to distance on the axle of imaging surface.

In one embodiment, this bugeye lens comprises diaphragm, and this diaphragm is arranged between these second lens and the 3rd lens.

In one embodiment, the face, image side of these the second lens is concave surface, and the face, image side of the 4th lens is concave surface at paraxial place, and the thing side of the 5th lens is convex surface at paraxial place.

The additional aspect of the utility model embodiment and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by the practice of the utility model embodiment.

Accompanying drawing explanation

Above-mentioned and/or the additional aspect of the utility model embodiment and advantage will become obvious and easy understand from accompanying drawing below combining to the description of embodiment, wherein:

Fig. 1 is the structural representation of the bugeye lens of embodiment 1;

Fig. 2 be the bugeye lens of embodiment 1 axle on chromaticity difference diagram (mm); Fig. 3 is the astigmatism figure (mm) of the bugeye lens of embodiment 1; Fig. 4 is the distortion figure (%) of the bugeye lens of embodiment 1; Fig. 5 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 1;

Fig. 6 is the structural representation of the bugeye lens of embodiment 2;

Fig. 7 be the bugeye lens of embodiment 2 axle on chromaticity difference diagram (mm); Fig. 8 is the astigmatism figure (mm) of the bugeye lens of embodiment 2; Fig. 9 is the distortion figure (%) of the bugeye lens of embodiment 2; Figure 10 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 2;

Figure 11 is the structural representation of the bugeye lens of embodiment 3;

Figure 12 be the bugeye lens of embodiment 3 axle on chromaticity difference diagram (mm); Figure 13 is the astigmatism figure (mm) of the bugeye lens of embodiment 3; Figure 14 is the distortion figure (%) of the bugeye lens of embodiment 3; Figure 15 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 3;

Figure 16 is the structural representation of the bugeye lens of embodiment 4;

Figure 17 be the bugeye lens of embodiment 4 axle on chromaticity difference diagram (mm); Figure 18 is the astigmatism figure (mm) of the bugeye lens of embodiment 4; Figure 19 is the distortion figure (%) of the bugeye lens of embodiment 4; Figure 20 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 4;

Figure 21 is the structural representation of the bugeye lens of embodiment 5;

Figure 22 be the bugeye lens of embodiment 5 axle on chromaticity difference diagram (mm); Figure 23 is the astigmatism figure (mm) of the bugeye lens of embodiment 5; Figure 24 is the distortion figure (%) of the bugeye lens of embodiment 5; Figure 25 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 5;

Figure 26 is the structural representation of the bugeye lens of embodiment 6;

Figure 27 be the bugeye lens of embodiment 6 axle on chromaticity difference diagram (mm); Figure 28 is the astigmatism figure (mm) of the bugeye lens of embodiment 6; Figure 29 is the distortion figure (%) of the bugeye lens of embodiment 6; Figure 30 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 6;

Figure 31 is the structural representation of the bugeye lens of embodiment 7;

Figure 32 be the bugeye lens of embodiment 7 axle on chromaticity difference diagram (mm); Figure 33 is the astigmatism figure (mm) of the bugeye lens of embodiment 7; Figure 34 is the distortion figure (%) of the bugeye lens of embodiment 7; Figure 35 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 7;

Figure 36 is the structural representation of the bugeye lens of embodiment 8;

Figure 37 be the bugeye lens of embodiment 8 axle on chromaticity difference diagram (mm); Figure 38 is the astigmatism figure (mm) of the bugeye lens of embodiment 8; Figure 39 is the distortion figure (%) of the bugeye lens of embodiment 8; Figure 40 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 8;

Figure 41 is the structural representation of the bugeye lens of embodiment 9;

Figure 42 be the bugeye lens of embodiment 9 axle on chromaticity difference diagram (mm); Figure 43 is the astigmatism figure (mm) of the bugeye lens of embodiment 9; Figure 44 is the distortion figure (%) of the bugeye lens of embodiment 9; Figure 45 is the ratio chromatism, figure (μm) of the bugeye lens of embodiment 9.

Embodiment

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Being exemplary below by the embodiment be described with reference to the drawings, only for explaining the utility model, and can not being interpreted as restriction of the present utility model.

In description of the present utility model, it is to be appreciated that term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or the implicit quantity indicating indicated technical characteristic.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise one or more described features.In description of the present utility model, the implication of " multiple " is two or more, unless otherwise expressly limited specifically.

In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " installation ", " being connected ", " connection " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or connect integratedly; Can be mechanical connection, also can be electrically connected or can intercom mutually; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals or the interaction relationship of two elements.For the ordinary skill in the art, the concrete meaning of above-mentioned term in the utility model can be understood as the case may be.

Disclosing hereafter provides many different embodiments or example is used for realizing different structure of the present utility model.Of the present utility model open in order to simplify, hereinafter the parts of specific examples and setting are described.Certainly, they are only example, and object does not lie in restriction the utility model.In addition, the utility model can in different example repeat reference numerals and/or reference letter, this repetition is to simplify and clearly object, itself does not indicate discussed various embodiment and/or relation between setting.In addition, the various specific technique that the utility model provides and the example of material, but those of ordinary skill in the art can recognize the application of other techniques and/or the use of other materials.

Refer to Fig. 1, a kind of bugeye lens of the utility model preferred embodiment, is comprised to image side successively by thing side:

Have the first lens L1 of negative refracting power, face, the image side S2 of the first lens L1 is concave surface;

Have the second lens L2 of positive refracting power, the thing side S3 of the second lens L2 is convex surface;

Have the 3rd lens L3 of positive refracting power, face, the image side S6 of the 3rd lens L3 is convex surface;

There is the 4th lens L4 of negative refracting power;

Have the 5th lens L5 of positive refracting power, face, the image side S10 of the 5th lens L5 is convex surface;

There is the 6th lens L6 of negative refracting power;

Described bugeye lens meets following relationship:

-2.0<f1/f<-1.0；

Wherein, f1 is the effective focal length of the first lens L1, and f is the effective focal length of bugeye lens.

Meet the bugeye lens of above-mentioned configuration, can reasonable disposition lens shape and focal power, while realizing ultra-wide angle, be conducive to revising all kinds of aberration, promote image quality, and ensure the miniaturization of camera lens.

Preferably, described bugeye lens meets following relationship:

1.3<f45/f<2.0；

Wherein, f45 is the synthesis focal length of the 4th lens L4 and the 5th lens L5, and f is the effective focal length of bugeye lens.

Meet the bugeye lens of above formula requirement, be conducive to the focal power of reasonable distribution system, update the system aberration, improve the image quality of camera lens.

Preferably, described bugeye lens meets following relationship:

-1.0<f1/f2<-0.2；

Wherein, f1 is the effective focal length of the first lens L1, and f2 is the effective focal length of the second lens L2.

Meet the bugeye lens of above formula requirement, be conducive to revising aberration, particularly reduce coma, promote image quality.

Preferably, described bugeye lens meets following relationship:

0.5<R2/R3<0.9；

Wherein, R2 is the radius-of-curvature of face, the image side S2 of the first lens L1; R3 is the radius-of-curvature of the thing side S3 of the second lens L2.

Meet the bugeye lens of above formula requirement, be conducive to promoting image quality, make center more even to edge entirety picture element.

Preferably, described bugeye lens meets following relationship:

1.0<DT11/DT62<1.5；

Wherein, DT11 is the effective radius of the thing side S1 of the first lens L1, and DT62 is the effective radius of face, the image side S12 of the 6th lens L6.

Meet the bugeye lens of above formula requirement, be conducive to uniform distribution aperture of lens, effectively reduce the volume of camera lens, and be easy to assembling.

Preferably, described bugeye lens meets following relationship:

0.8<f3/f5<2.0；

0.3<f4/f6<2.0；

Wherein, f3 is the effective focal length of the 3rd lens L3, and f5 is the effective focal length of the 5th lens L5, and f4 is the effective focal length of the 4th lens L4, and f6 is the effective focal length of the 6th lens L6.

Meet the bugeye lens of above formula requirement, be conducive to effectively revising aberration, correct image planes distortion, realize, from center to edge, all there is high imaging performance.

Preferably, described bugeye lens meets following relationship:

0.2mm ^-1<tan(HFOV)/TTL<0.5mm ^-1；

Wherein, HFOV is the half at the maximum field of view angle of bugeye lens, TTL be the thing side S1 to imaging surface S15 of the first lens L1 axle on distance.

Meet the bugeye lens of above formula requirement, while being conducive to realizing ultra-wide angle, ensure the miniaturization of camera lens further.

Preferably, described bugeye lens comprises diaphragm STO, and diaphragm STO is arranged between the second lens L2 and the 3rd lens L3.

Meet the bugeye lens of above-mentioned requirements, be conducive to balancing eccentric tolerance better, effectively reduce tolerance sensitivities.

Preferably, in described bugeye lens, face, the image side S4 of the second lens L2 is concave surface, and face, the image side S8 of the 4th lens L4 is concave surface at paraxial place, and the thing side S9 of the 5th lens L5 is convex surface at paraxial place.

Meet the bugeye lens of above-mentioned requirements, be conducive to revising aberration further, improve image quality.

During imaging, light images in imaging surface S15 through after six-element lens after having the optical filter L7 of thing side surface S13 and surface, image side S14.

In some embodiments, the first lens L1, the second lens L2, the 3rd lens L3, the 4th lens L4, the 5th lens L5 and the 6th lens L6 are non-spherical lens.

Aspheric type is determined by following formula:

$x=\frac{{\mathrm{ch}}^2}{1+\sqrt{1-(k+1)c^2{h}^2}}+{\mathrm{\&Sigma;Aih}}^i$

Wherein, h is that in aspheric surface, arbitrary point is to the height of optical axis, and c is vertex curvature, and k is conic constants, and Ai is the correction factor on aspheric surface i-th-th rank.

Embodiment 1

Incorporated by reference to Fig. 1 ~ Fig. 5, in embodiment 1, bugeye lens meets the condition of table 1 ~ 2 below:

Table 1

Face number	Surface type	Radius-of-curvature	Thickness	Refractive index/Abbe number	Circular cone coefficient
						OBJ	Sphere	Infinite	Infinite	--	--
S1	Aspheric surface	-123.3599	0.2400	1.544/56.11	-71.8954
						S2	Aspheric surface	1.1911	0.5768	--	-2.7306
S3	Aspheric surface	0.9635	0.4391	1.640/23.53	-0.3194
						S4	Aspheric surface	1.1773	0.3114	--	1.7582
STO	Sphere	Infinite	0.0344	--	--
						S5	Aspheric surface	3.9066	0.8140	1.544/56.11	17.3592
S6	Aspheric surface	-0.9845	0.0300	--	0.0120
						S7	Aspheric surface	55.8310	0.2200	1.640/23.53	45.8391
S8	Aspheric surface	1.9431	0.1063	--	-5.2871
						S9	Aspheric surface	55.1249	0.8842	1.544/56.11	-99.0000
S10	Aspheric surface	-0.9768	0.0300	--	-0.7948
						S11	Aspheric surface	0.9022	0.2774	1.640/23.53	-4.6560
S12	Aspheric surface	0.5536	0.6492	--	-3.3188
						S13	Sphere	Infinite	0.1100	1.517/64.17	--
S14	Sphere	Infinite	0.3176	--	--
						S15	Sphere	Infinite	--	--	--

Table 2

Face number

A4

A6

A8

A10

A12

A14

A16

S1

7.4709E-02

-3.7627E-02

1.5476E-02

-4.5070E-03

8.1868E-04

-8.3182E-05

3.6949E-06

S2

3.6040E-02

-5.2840E-03

-5.9177E-02

4.7343E-02

-1.5954E-02

2.5763E-03

-1.6194E-04

S3

-1.6624E-01

5.0105E-02

-5.2294E-01

1.5601E+00

-2.8271E+00

2.5124E+00

-8.6077E-01

S4

3.3119E-02

1.6356E-02

2.9977E+00

-1.5930E+01

4.7380E+01

-6.0740E+01

2.6510E+01

S5

1.5912E-03

-2.2891E-01

2.4645E-02

2.5698E+00

-1.3754E+01

3.0975E+01

-2.6150E+01

S6

-1.4916E-01

-1.4238E-01

3.4041E+00

-1.4400E+01

2.4344E+01

-1.7887E+01

4.7790E+00

S7

-6.8368E-01

3.4498E-01

2.6939E+00

-9.3250E+00

1.0109E+01

-4.5259E+00

1.0429E+00

S8

-2.7541E-01

-3.2837E-01

2.1668E+00

-3.9864E+00

3.5785E+00

-1.5885E+00

2.7378E-01

S9

3.9180E-01

-1.2248E+00

1.8308E+00

-1.4653E+00

4.8970E-01

4.2378E-02

-4.9033E-02

S10

5.0454E-01

-7.5241E-01

1.1857E+00

-1.4634E+00

1.0722E+00

-4.1933E-01

6.8185E-02

S11

-1.3365E-01

4.1737E-02

3.1856E-02

-5.9141E-02

2.4523E-02

-3.5543E-03

1.4016E-04

S12

-1.8741E-01

1.8546E-01

-1.3013E-01

5.3444E-02

-1.3027E-02

1.7405E-03

-9.6852E-05

In addition, f1=-2.159mm; F2=4.560mm, f3=1.530mm, f4=-3.128mm, f5=1.768mm, f6=-3.230mm and f=1.44mm; HFOV=61.61 °; TTL=5.04mm; Fno=2.17.

Embodiment 2

Incorporated by reference to Fig. 6 ~ Figure 10, in embodiment 2, bugeye lens meets the condition of table 3 ~ 4 below:

Table 3

Face number	Surface type	Radius-of-curvature	Thickness	Refractive index/Abbe number	Circular cone coefficient
						OBJ	Sphere	Infinite	Infinite	--	--
S1	Aspheric surface	-18.5416	0.3866	1.544/56.11	73.8351
						S2	Aspheric surface	1.1760	0.1820	--	-3.9127
S3	Aspheric surface	1.5108	0.4858	1.544/56.11	0.0365
						S4	Aspheric surface	3.6365	0.6705	--	4.2673
STO	Sphere	Infinite	0.0953	--	--
						S5	Aspheric surface	3.2610	0.8733	1.544/56.11	15.9549
S6	Aspheric surface	-1.1853	0.0371	--	0.0455
						S7	Aspheric surface	-27.9409	0.3659	1.640/23.53	49.1780
S8	Aspheric surface	2.1831	0.0710	--	-0.6131
						S9	Aspheric surface	11.7513	1.2022	1.544/56.11	-82.3122
S10	Aspheric surface	-0.9433	0.0504	--	-0.8985
						S11	Aspheric surface	1.9225	0.4111	1.640/23.53	-14.7615
S12	Aspheric surface	0.7660	0.6238	--	-4.2347
						S13	Sphere	Infinite	0.2124	1.517/64.17	--
S14	Sphere	Infinite	0.3974	--	--
						S15	Sphere	Infinite	--	--	--

Table 4

Face number

A4

A6

A8

A10

A12

A14

A16

S1

9.3179E-02

-6.7472E-02

4.4410E-02

-1.8716E-02

4.6725E-03

-6.3402E-04

3.6577E-05

S2

1.7096E-01

-4.0349E-01

2.6304E-01

-3.8625E-02

-2.7557E-02

1.2478E-02

-1.5170E-03

S3

-1.5204E-01

-1.5887E-01

1.9668E-01

-6.4159E-02

4.2650E-04

3.3802E-04

3.0960E-04

S4

1.2760E-01

1.3420E-01

1.6507E-01

-2.1698E-01

2.2334E-01

8.9341E-01

-5.3500E-01

S5

-2.6458E-02

-9.4446E-02

-5.4322E-02

7.1074E-03

5.1275E-01

-1.9683E-01

-1.5234E+00

S6

7.2119E-02

3.3190E-02

-1.7579E-02

-1.5692E-02

-3.8402E-02

-5.7187E-03

2.0259E-01

S7

-2.3667E-01

6.5642E-02

4.9429E-02

-1.3082E-01

3.6763E-02

2.6234E-02

6.0750E-03

S8

-1.5097E-01

7.3013E-02

-3.8548E-02

5.7199E-03

3.3318E-03

4.8578E-04

-1.7240E-03

S9

1.6337E-01

-1.5202E-01

6.9574E-02

-1.0023E-02

-2.0358E-03

7.4254E-04

-4.2189E-04

S10

1.6316E-01

-6.1347E-02

1.6231E-02

6.6097E-03

-1.5078E-03

-4.2891E-04

9.0984E-05

S11

-3.0913E-01

2.9890E-01

-3.2708E-01

2.5955E-01

-1.3274E-01

3.7267E-02

-4.1814E-03

S12

-1.7578E-01

1.2261E-01

-6.5231E-02

2.3754E-02

-5.5099E-03

7.0976E-04

-3.7786E-05

In addition, f1=-2.012mm; F2=4.381mm, f3=1.711mm, f4=-3.127mm, f5=1.655mm, f6=-2.2.95mm and f=1.710mm; HFOV=55.77 °; TTL=6.06mm; Fno=2.25.

Embodiment 3

Incorporated by reference to Figure 11 ~ Figure 15, in embodiment 3, bugeye lens meets the condition of table 5 ~ 6 below:

Table 5

Face number	Surface type	Radius-of-curvature	Thickness	Refractive index/Abbe number	Circular cone coefficient
						OBJ	Sphere	Infinite	600.0000	--	--
S1	Aspheric surface	-17.8164	0.4371	1.544/56.11	0.0000
						S2	Aspheric surface	1.1767	0.2290	--	-4.3866
S3	Aspheric surface	1.2512	0.3785	1.544/56.11	-0.0366
						S4	Aspheric surface	2.8344	0.5659	--	7.8950
STO	Sphere	Infinite	0.0152	--	--
						S5	Aspheric surface	3.1581	0.7622	1.544/56.11	8.5848
S6	Aspheric surface	-1.1884	0.0360	--	0.0769
						S7	Aspheric surface	97.3054	0.3000	1.640/23.53	0.0000
S8	Aspheric surface	1.6836	0.0663	--	-13.6869
						S9	Aspheric surface	6.8162	0.9960	1.544/56.11	-15.5577
S10	Aspheric surface	-0.9101	0.2420	--	-1.0769
						S11	Aspheric surface	2.0786	0.3600	1.640/23.53	-55.8211
S12	Aspheric surface	0.7542	0.3918	--	-5.4995
						S13	Sphere	Infinite	0.2100	1.517/64.17	--
S14	Sphere	Infinite	0.4000	--	--
						S15	Sphere	Infinite	--	--	--

Table 6

Face number

A4

A6

A8

A10

A12

A14

A16

S1

1.0349E-01

-7.1980E-02

4.4693E-02

-1.8570E-02

4.6772E-03

-6.3471E-04

3.5970E-05

S2

2.0180E-01

-4.1426E-01

2.6158E-01

-3.7709E-02

-2.7358E-02

1.2512E-02

-1.5616E-03

S3

-1.7438E-01

-1.9207E-01

2.2111E-01

-7.0151E-02

-1.1174E-02

-6.5730E-03

3.4901E-03

S4

1.4207E-01

2.6013E-01

-1.6977E+00

1.0758E+01

-2.9529E+01

4.1293E+01

-2.2365E+01

S5

2.7499E-02

1.0372E-01

-5.3796E-01

-8.4483E-01

3.8783E+00

4.3233E+00

-1.5324E+01

S6

1.7782E-01

-2.8896E-01

3.0585E-01

-8.7605E-02

-4.6270E-01

-4.4175E-01

1.2914E+00

S7

-3.6038E-01

3.3346E-01

-3.2795E-01

-8.9521E-02

1.2264E-01

-3.8073E-01

4.4085E-01

S8

-1.0147E-01

1.0710E-01

-8.8491E-02

-1.7013E-03

2.5915E-02

1.7929E-02

-1.4870E-02

S9

1.2914E-01

-1.5380E-01

8.0697E-02

-9.2045E-03

-2.8889E-03

6.0592E-04

-5.2194E-04

S10

2.0788E-01

-9.7067E-02

2.4805E-02

7.7005E-03

-8.7323E-04

-5.4965E-04

-1.9316E-04

S11

-1.7432E-01

-5.0952E-02

2.1712E-01

-2.7078E-01

1.5011E-01

-3.6985E-02

3.3186E-03

S12

-1.6310E-01

1.1467E-01

-6.5395E-02

2.3619E-02

-5.4257E-03

7.1984E-04

-4.0830E-05

In addition, f1=-2.006mm; F2=3.784mm, f3=1.686mm, f4=-2.661mm, f5=1.541mm, f6=-2.055mm and f=1.682mm; HFOV=55.0 °; TTL=5.39mm; Fno=2.15.

Embodiment 4

Incorporated by reference to Figure 16 ~ Figure 20, in embodiment 4, bugeye lens meets the condition of table 7 ~ 8 below:

Table 7

Face number	Surface type	Radius-of-curvature	Thickness	Refractive index/Abbe number	Circular cone coefficient
						OBJ	Sphere	Infinite	Infinite	--	--
S1	Aspheric surface	7.7055	0.4249	1.544/56.11	0.0139
						S2	Aspheric surface	1.5744	1.2896	--	-1.4205
S3	Aspheric surface	2.0613	0.5928	1.640/23.53	-0.6410
						S4	Aspheric surface	2.2835	1.2747	--	-1.0731
STO	Sphere	Infinite	-0.0475	--	--
						S5	Aspheric surface	4.4384	1.2956	1.544/56.11	3.9811
S6	Aspheric surface	-1.6669	0.1541	--	-0.1885
						S7	Aspheric surface	13.2533	0.3190	1.640/23.53	-75.9957
S8	Aspheric surface	2.4207	0.2028	--	-9.3721
						S9	Aspheric surface	6.9311	1.9883	1.544/56.11	-117.6222
S10	Aspheric surface	-1.6207	0.0283	--	-0.7205
						S11	Aspheric surface	7.9368	0.6775	1.640/23.53	-93.8920
S12	Aspheric surface	1.6865	0.9482	--	-5.0431
						S13	Sphere	Infinite	0.3000	1.517/64.17	--
S14	Sphere	Infinite	0.2998	--	--
						S15	Sphere	Infinite	--	--	--

Table 8

Face number

A4

A6

A8

A10

A12

A14

A16

S1

6.4182E-03

-2.5502E-03

5.3103E-04

-6.0910E-05

4.0900E-06

-1.4995E-07

2.3257E-09

S2

1.4283E-02

2.0098E-04

-1.9574E-03

5.8462E-04

-7.8780E-05

4.7111E-06

-8.0581E-08

S3

9.1121E-03

1.5896E-02

-4.7944E-03

-1.3556E-03

3.2931E-04

-2.0478E-07

-8.3318E-08

S4

5.4757E-02

5.5297E-02

-3.6315E-02

1.3750E-02

-1.4187E-04

-1.1011E-04

-9.6971E-05

S5

-6.6215E-03

-3.3673E-02

2.9302E-02

-1.2307E-02

-6.6570E-02

6.4973E-02

-8.9526E-03

S6

3.4122E-02

-9.1267E-02

1.7437E-01

-2.0452E-01

1.1517E-01

-2.8153E-02

8.7603E-04

S7

-1.1964E-01

-6.1668E-03

1.1594E-01

-1.2631E-01

5.1258E-02

-6.9348E-03

-4.4053E-04

S8

-5.5267E-02

-2.9527E-02

7.2520E-02

-5.0979E-02

1.7396E-02

-2.8530E-03

1.7091E-04

S9

7.7204E-02

-1.0383E-01

6.1951E-02

-1.8808E-02

2.3251E-03

8.8906E-05

-3.2841E-05

S10

9.8849E-02

-6.1495E-02

3.9165E-02

-1.8602E-02

5.1864E-03

-7.6153E-04

4.6039E-05

S11

-4.1307E-02

-2.5653E-02

1.9941E-02

-6.7107E-03

1.0654E-03

-6.3469E-05

-5.9738E-09

S12

-4.6370E-02

9.1661E-03

-8.6696E-04

-1.1756E-06

5.7030E-06

-2.7420E-07

-5.0214E-12

In addition, f1=-3.175m; F2=16.065mm, f3=2.399mm, f4=-4.648mm, f5=2.621mm, f6=-3.470mm and f=m2.244m; HFOV=68.50 °; TTL=9.75mm; Fno=2.43.

Embodiment 5

Incorporated by reference to Figure 21 ~ Figure 25, in embodiment 5, bugeye lens meets the condition of table 9 ~ 10 below:

Table 9

Face number	Surface type	Radius-of-curvature	Thickness	Refractive index/Abbe number	Circular cone coefficient
						OBJ	Sphere	Infinite	Infinite	--	--
S1	Aspheric surface	5.8405	0.2000	1.544/56.11	-8.4779
						S2	Aspheric surface	1.4638	2.0366	--	-1.1533
S3	Aspheric surface	2.3613	0.4713	1.640/23.53	-0.4554
						S4	Aspheric surface	3.1707	0.9978	--	-1.2910
STO	Sphere	Infinite	0.0530	--	--
						S5	Aspheric surface	3.3439	1.5011	1.544/56.11	4.4363
S6	Aspheric surface	-1.8076	0.0300	--	0.0297
						S7	Aspheric surface	-1000.0000	0.2812	1.640/23.53	-4.91E+22
S8	Aspheric surface	2.5027	0.1796	--	-15.3893
						S9	Aspheric surface	12.7592	1.7257	1.544/56.11	-475.2615
S10	Aspheric surface	-1.3731	0.0300	--	-0.7155
						S11	Aspheric surface	2.2538	0.4707	1.640/23.53	-13.6281
S12	Aspheric surface	1.0624	0.9482	--	-3.8884
						S13	Sphere	Infinite	0.3000	1.517/64.17	--
S14	Sphere	Infinite	0.2998	--	--
						S15	Sphere	Infinite	--	--	--

Table 10

Face number

A4

A6

A8

A10

A12

A14

A16

S1

5.0526E-03

-2.4912E-03

5.3365E-04

-6.1004E-05

4.0970E-06

-1.4948E-07

2.3015E-09

S2

9.8121E-03

-1.4267E-04

-1.8146E-03

5.8081E-04

-7.8947E-05

5.4437E-06

-2.3628E-08

S3

1.2042E-02

1.4915E-02

-4.8611E-03

-1.4598E-03

3.2931E-04

-2.0478E-07

-8.3318E-08

S4

3.9647E-02

3.7209E-02

-2.5742E-02

5.8875E-03

-1.4187E-04

-1.1011E-04

-9.6971E-05

S5

-6.9915E-03

-1.6653E-02

1.5460E-02

-1.3300E-02

-6.6570E-02

6.4973E-02

-8.9526E-03

S6

3.3494E-02

-1.0804E-01

1.6763E-01

-2.0327E-01

1.1517E-01

-2.8153E-02

8.7603E-04

S7

-1.8809E-01

-4.1898E-03

1.1273E-01

-1.4424E-01

5.1258E-02

-6.9348E-03

-4.4053E-04

S8

-6.7536E-02

-3.2444E-02

7.2735E-02

-5.0573E-02

1.7396E-02

-2.8530E-03

1.7091E-04

S9

6.3043E-02

-1.0199E-01

6.2439E-02

-1.8935E-02

2.3251E-03

8.8906E-05

-3.2841E-05

S10

1.1064E-01

-6.4646E-02

3.9609E-02

-1.8527E-02

5.1864E-03

-7.6153E-04

4.6039E-05

S11

-4.1184E-02

-2.4858E-02

1.9232E-02

-6.6449E-03

1.0654E-03

-6.3469E-05

-5.9738E-09

S12

-4.5799E-02

8.9996E-03

-8.9697E-04

1.0187E-06

5.7030E-06

-2.7420E-07

-5.0214E-12

In addition, f1=-3.637mm; F2=11.684mm, f3=2.396mm, f4=-3.872mm, f5=2.373mm, f6=-3.689mm and f=1.846mm; HFOV=68.50 °; TTL=9.52mm; Fno=2.43.

Embodiment 6

Incorporated by reference to Figure 26 ~ Figure 30, in embodiment 6, bugeye lens meets the condition of table 11 ~ 12 below:

Table 11

Table 12

Face number

A4

A6

A8

A10

A12

A14

A16

S1

5.6863E-03

-2.5044E-03

5.3141E-04

-6.0803E-05

4.0906E-06

-1.4976E-07

2.3305E-09

S2

2.0083E-02

3.0799E-04

-2.0004E-03

5.8374E-04

-7.8120E-05

4.7544E-06

-9.4800E-08

S3

7.4110E-03

1.6970E-02

-4.5393E-03

-1.4067E-03

3.2931E-04

-2.0478E-07

-8.3318E-08

S4

4.2380E-02

4.8075E-02

-3.1875E-02

1.1393E-02

-1.4187E-04

-1.1011E-04

-9.6971E-05

S5

-3.8581E-03

-2.4740E-02

2.7867E-02

-1.1789E-02

-6.6570E-02

6.4973E-02

-8.9526E-03

S6

3.7361E-02

-9.6416E-02

1.7116E-01

-2.0238E-01

1.1517E-01

-2.8153E-02

8.7603E-04

S7

-1.5161E-01

-7.7507E-03

1.1689E-01

-1.3292E-01

5.1258E-02

-6.9348E-03

-4.4053E-04

S8

-5.5222E-02

-3.1351E-02

7.2480E-02

-5.0704E-02

1.7396E-02

-2.8530E-03

1.7091E-04

S9

7.2895E-02

-1.0234E-01

6.2121E-02

-1.8942E-02

2.3251E-03

8.8906E-05

-3.2841E-05

S10

1.0141E-01

-6.1533E-02

3.9173E-02

-1.8612E-02

5.1864E-03

-7.6153E-04

4.6039E-05

S11

-2.9696E-02

-2.4893E-02

1.9774E-02

-6.7398E-03

1.0654E-03

-6.3469E-05

-5.9738E-09

S12

-4.3111E-02

9.0346E-03

-8.8953E-04

-2.2113E-07

5.7030E-06

-2.7420E-07

-5.0214E-12

In addition, f1=-3.441mm; F2=12.346mm, f3=2.373mm, f4=-4.400mm, f5=2.468mm, f6=-3.400mm and f=1.903mm; HFOV=68.5 °; TTL=9.53mm; Fno=68.50.

Embodiment 7

Incorporated by reference to Figure 31 ~ Figure 35, in embodiment 7, bugeye lens meets the condition of table 13 ~ 14 below:

Table 13

Table 14

Face number

A4

A6

A8

A10

A12

A14

A16

S1

8.8037E-03

-2.5822E-03

5.2892E-04

-6.1062E-05

4.0859E-06

-1.4988E-07

2.3298E-09

S2

1.6229E-02

5.1168E-04

-1.9436E-03

5.8274E-04

-7.9049E-05

4.6343E-06

-7.0178E-08

S3

-1.3527E-03

2.0392E-02

-1.6129E-03

-1.8357E-03

3.2931E-04

-2.0478E-07

-8.3318E-08

S4

3.4300E-02

7.0600E-02

-5.0304E-02

2.3709E-02

-1.4187E-04

-1.1011E-04

-9.6971E-05

S5

-4.4782E-03

-2.2283E-02

2.5445E-02

-1.8860E-02

-6.6570E-02

6.4973E-02

-8.9526E-03

S6

4.1188E-02

-1.1168E-01

1.7310E-01

-2.0196E-01

1.1517E-01

-2.8153E-02

8.7603E-04

S7

-1.7016E-01

9.6500E-03

1.1352E-01

-1.3958E-01

5.1258E-02

-6.9348E-03

-4.4053E-04

S8

-5.2024E-02

-3.0148E-02

7.2134E-02

-5.0726E-02

1.7396E-02

-2.8530E-03

1.7091E-04

S9

7.2677E-02

-1.0296E-01

6.2265E-02

-1.8951E-02

2.3251E-03

8.8906E-05

-3.2841E-05

S10

1.2169E-01

-6.0634E-02

3.9433E-02

-1.8670E-02

5.1864E-03

-7.6153E-04

4.6039E-05

S11

-1.9592E-02

-3.0052E-02

2.1662E-02

-7.0609E-03

1.0654E-03

-6.3469E-05

-5.9738E-09

S12

-4.7488E-02

9.4049E-03

-9.0197E-04

-8.7368E-07

5.7030E-06

-2.7420E-07

-5.0214E-12

In addition, f1=-3.249mm; F2=8.607mm, f3=2.364mm, f4=-3.924mm, f5=2.140mm, f6=-3.991mm and f=1.839mm; HFOV=68.50 °; TTL=8.65mm; Fno=2.43.

Embodiment 8

Incorporated by reference to Figure 36 ~ Figure 40, in embodiment 8, bugeye lens meets the condition of table 15 ~ 16 below:

Table 15

Face number	Surface type	Radius-of-curvature	Thickness	Refractive index/Abbe number	Circular cone coefficient
						OBJ	Sphere	Infinite	Infinite	--	--
S1	Aspheric surface	7.7117	0.2004	1.544/56.11	-2.8367
						S2	Aspheric surface	1.9430	1.5157	--	-1.3493
S3	Aspheric surface	2.5339	0.4076	1.640/23.53	-0.8386
						S4	Aspheric surface	3.5745	1.0545	--	-4.5177
STO	Sphere	Infinite	0.0300	--	--
						S5	Aspheric surface	-1000.0000	1.0603	1.544/56.11	-5817.5980
S6	Aspheric surface	-1.6025	0.2523	--	-0.0914
						S7	Aspheric surface	8.3592	0.2232	1.640/23.53	-17.5686
S8	Aspheric surface	2.3512	0.2028	--	-10.3337
						S9	Aspheric surface	14.8201	1.9138	1.544/56.11	-955.4503
S10	Aspheric surface	-1.5844	0.4718	--	-0.6669
						S11	Aspheric surface	12.6931	0.6393	1.640/23.53	17.7527
S12	Aspheric surface	1.6818	0.9482	--	-4.7866
						S13	Sphere	Infinite	0.3000	1.517/64.17	--
S14	Sphere	Infinite	0.2998	--	--
						S15	Sphere	Infinite	--	--	--

Table 16

Face number

A4

A6

A8

A10

A12

A14

A16

S1

5.5425E-03

-2.5169E-03

5.3243E-04

-6.1082E-05

4.0737E-06

-1.5053E-07

2.3980E-09

S2

9.9376E-03

2.4227E-04

-1.9279E-03

5.8717E-04

-7.8691E-05

4.6940E-06

-8.7345E-08

S3

5.6115E-03

1.4911E-02

-4.9078E-03

-1.2229E-03

3.2931E-04

-2.0478E-07

-8.3318E-08

S4

3.1441E-02

3.9369E-02

-2.8012E-02

7.3059E-03

-1.4187E-04

-1.1011E-04

-9.6971E-05

S5

-3.8773E-02

-1.9090E-02

-2.1200E-02

1.7979E-02

-6.6570E-02

6.4973E-02

-8.9526E-03

S6

4.0559E-02

-1.0142E-01

1.7137E-01

-2.0193E-01

1.1517E-01

-2.8153E-02

8.7603E-04

S7

-1.1890E-01

-3.4176E-03

1.1860E-01

-1.2449E-01

5.1258E-02

-6.9348E-03

-4.4053E-04

S8

-4.8048E-02

-2.9471E-02

7.1823E-02

-5.0996E-02

1.7396E-02

-2.8530E-03

1.7091E-04

S9

8.5066E-02

-1.0349E-01

6.2049E-02

-1.8875E-02

2.3251E-03

8.8906E-05

-3.2841E-05

S10

9.2412E-02

-5.8941E-02

3.9485E-02

-1.8651E-02

5.1861E-03

-7.6153E-04

4.6039E-05

S11

-3.3582E-02

-2.6133E-02

1.9845E-02

-6.7303E-03

1.0654E-03

-6.3469E-05

-5.9738E-09

S12

-4.2366E-02

8.4794E-03

-8.5809E-04

4.4985E-07

5.6884E-06

-2.6820E-07

-6.6844E-12

In addition, f1=-4.817mm; F2=11.706mm, f3=m2.939m, f4=-5.150mm, f5=2.734mm, f6=-3.078mm and f=2.687mm; HFOV=98.50 °; TTL=9.52mm; Fno=2.90.

Embodiment 9

Incorporated by reference to Figure 41 ~ Figure 45, in embodiment 9, bugeye lens meets the condition of table 17 ~ 18 below:

Table 17

Face number	Surface type	Radius-of-curvature	Thickness	Refractive index/Abbe number	Circular cone coefficient
						OBJ	Sphere	Infinite	Infinite	--	--
S1	Aspheric surface	6.9449	0.2001	1.544/56.11	2.8707
						S2	Aspheric surface	1.6506	1.4177	--	-1.3145
S3	Aspheric surface	2.2976	0.4746	1.640/23.53	-0.4717
						S4	Aspheric surface	2.6311	1.3256	--	-1.2043
STO	Sphere	Infinite	0.0300	--	--
						S5	Aspheric surface	3.4607	1.3194	1.544/56.11	4.6323
S6	Aspheric surface	-1.7900	0.0855	--	-0.1372
						S7	Aspheric surface	8.2861	0.2623	1.640/23.53	-90.3919
S8	Aspheric surface	2.2996	0.1761	--	-12.0529
						S9	Aspheric surface	8.8257	1.8883	1.544/56.11	-376.2865
S10	Aspheric surface	-1.5853	0.4291	--	-0.7084
						S11	Aspheric surface	-1.6223	0.3681	1.640/23.53	-3.9495
S12	Aspheric surface	-1000.0000	0.9482	--	75.4800
						S13	Sphere	Infinite	0.3000	1.517/64.17	--
S14	Sphere	Infinite	0.2998	--	--
						S15	Sphere	Infinite	--	--	--

Table 18

Face number

A4

A6

A8

A10

A12

A14

A16

S1

8.3068E-03

-2.5933E-03

5.2924E-04

-6.0841E-05

4.0702E-06

-1.5171E-07

2.6844E-09

S2

2.4309E-02

2.0100E-03

-1.8365E-03

5.7923E-04

-8.0729E-05

4.4098E-06

-1.2476E-07

S3

1.5647E-02

1.3519E-02

-5.0431E-03

-1.2313E-03

3.2931E-04

-2.0478E-07

-8.3318E-08

S4

5.1448E-02

4.6340E-02

-3.2384E-02

1.1713E-02

-1.4187E-04

-1.1011E-04

-9.6971E-05

S5

-6.1425E-03

-3.1201E-02

3.8129E-02

-2.0120E-02

-6.6570E-02

6.4973E-02

-8.9526E-03

S6

3.0938E-02

-8.8402E-02

1.7550E-01

-2.0527E-01

1.1517E-01

-2.8153E-02

8.7603E-04

S7

-1.4177E-01

-5.1369E-03

1.1939E-01

-1.3111E-01

5.1258E-02

-6.9348E-03

-4.4053E-04

S8

-5.6282E-02

-3.2254E-02

7.2293E-02

-5.0350E-02

1.7396E-02

-2.8530E-03

1.7091E-04

S9

6.5975E-02

-1.0147E-01

6.2480E-02

-1.8857E-02

2.3251E-03

8.8906E-05

-3.2841E-05

S10

9.5765E-02

-5.9672E-02

3.8995E-02

-1.8658E-02

5.1864E-03

-7.6153E-04

4.6039E-05

S11

-2.1467E-02

-2.6243E-02

1.9608E-02

-6.8166E-03

1.0654E-03

-6.3469E-05

-5.9738E-09

S12

-3.6376E-02

7.8177E-03

-8.4145E-04

-8.5742E-07

5.7018E-06

-2.7420E-07

-5.0221E-12

In addition, f1=-4.020mm; F2=18.050mm, f3=2.371mm, f4=-5.024mm, f5=2.630mm, f6=-2.521mm and f=2.550mm; HFOV=68.50 °; TTL=9.52mm; Fno=2.76.

In embodiment 1 ~ 9, each conditional meets the condition of form below:

In the description of this instructions, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " illustrative examples ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with described embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, identical embodiment or example are not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.

In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or imply the quantity indicating indicated technical characteristic.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise at least one this feature.In description of the present utility model, the implication of " multiple " is at least two, such as two, three etc., unless otherwise expressly limited specifically.

Although illustrate and described embodiment of the present utility model above, be understandable that, above-described embodiment is exemplary, can not be interpreted as restriction of the present utility model, those of ordinary skill in the art can change above-described embodiment, revises, replace and modification in scope of the present utility model.

Claims (9)

1. a bugeye lens, is characterized in that, is comprised successively to image side by thing side:

Have the first lens of negative refracting power, the face, image side of these the first lens is concave surface;

Have the second lens of positive refracting power, the thing side of these the second lens is convex surface;

Have the 3rd lens of positive refracting power, the face, image side of the 3rd lens is convex surface;

There are the 4th lens of negative refracting power;

Have the 5th lens of positive refracting power, the face, image side of the 5th lens is convex surface;

There are the 6th lens of negative refracting power;

This bugeye lens meets following relationship:

-2.0<f1/f<-1.0；

Wherein, f1 is the effective focal length of these the first lens, and f is the effective focal length of this bugeye lens.

2. bugeye lens according to claim 1, is characterized in that: this bugeye lens meets following relationship:

1.3<f45/f<2.0；

Wherein, f45 is the synthesis focal length of the 4th lens and the 5th lens.

3. bugeye lens according to claim 1, is characterized in that, this bugeye lens meets following relationship:

-1.0<f1/f2<-0.2；

Wherein, f2 is the effective focal length of these the second lens.

4. bugeye lens according to claim 1, is characterized in that: this bugeye lens meets following relationship:

0.5<R2/R3<0.9；

Wherein, R2 is the radius-of-curvature in the face, image side of these the first lens; R3 is the radius-of-curvature of the thing side of these the second lens.

5. bugeye lens according to claim 1, is characterized in that: this bugeye lens meets following relationship:

1.0<DT11/DT62<1.5；

Wherein, DT11 is the effective radius of the thing side of these the first lens, and DT62 is the effective radius in the face, image side of the 6th lens.

6. bugeye lens according to claim 1, is characterized in that: this bugeye lens meets following relationship:

0.8<f3/f5<2.0；

0.3<f4/f6<2.0；

Wherein, f3 is the effective focal length of the 3rd lens, and f5 is the effective focal length of the 5th lens, and f4 is the effective focal length of the 4th lens, and f6 is the effective focal length of the 6th lens.

7. bugeye lens according to claim 1, is characterized in that: this bugeye lens meets following relationship:

0.2mm ^-1<tan(HFOV)/TTL<0.5mm ^-1；

Wherein, HFOV is the half at the maximum field of view angle of this bugeye lens, and TTL is that the thing side of these the first lens is to distance on the axle of imaging surface.

8. bugeye lens according to claim 1, is characterized in that, this bugeye lens comprises diaphragm, and this diaphragm is arranged between these second lens and the 3rd lens.

9. bugeye lens according to claim 1, is characterized in that, the face, image side of these the second lens is concave surface, and the face, image side of the 4th lens is concave surface at paraxial place, and the thing side of the 5th lens is convex surface at paraxial place.