CN204009194U - The interactive camera lens of 3D - Google Patents

Abstract

The utility model provides the interactive camera lens of a kind of 3D, the miniature imaging lens combination being formed by five groups of lens, from thing side to sequentially comprising as side: the first lens of the negative refracting power of tool, its thing side is convex surface, is concave surface as side; The second lens of the positive refracting power of tool, it is convex surface as side; The 3rd lens of the negative refracting power of tool, it is concave surface as side; The 4th lens of the positive refracting power of tool, it is convex surface as side; The 5th lens of the negative refracting power of tool, its thing side is convex surface, is concave surface as side.Described camera lens meets 0< (R3+R4)/(R3-R4) <1.2,7<T12/T23<25, wherein R3, R4 are respectively the radius-of-curvature of the second He Xiang side, lens thing side, T12 is the spacing on optical axis of first lens and the second lens, and T23 is the second lens and the spacing of the 3rd lens on optical axis.The utility model configures by said lens, can ensure possess the advantage such as large aperture, miniaturization under wide-angle, high-resolution prerequisite, can effectively eliminate simultaneously heat poor, carry out good correction to distorting.

Description

The interactive camera lens of 3D

Technical field

The utility model relates to the interactive camera lens of a kind of 3D, the miniature imaging lens combination being made up of five groups of lens.

Background technology

Along with the development of CMOS chip technology, the Pixel Dimensions of chip is more and more less at present, and also more and more higher to the image quality requirement of the optical system matching, the optical lens size of mobile phone or digital camera also becomes more and more less; Along with the development of technology, also produce the interactive camera lens of 3D, nowadays, the interactive camera lens of 3D, has started the digital 3 D world to incorporate in our daily life.General slim camera lens is because size is little, and eyeglass quantity is also fewer, cannot meet the high-quality parsing requirement of 3D camera lens, certainly will will increase like this quantity of eyeglass, makes the optics overall length of camera lens increase simultaneously, is difficult to have concurrently the characteristic of miniaturization.Publication number is " CN103477264 ", name is called the utility model patent of " image taking lens and image picking-up apparatus ", comprise five lens, be specially the first lens with negative refracting power, there are the second lens of positive refracting power, there are the 3rd lens of negative refracting power, there are the 4th lens of positive refracting power, there are the 5th lens of negative refracting power, adopt such structure, although reach high resolving power, the characteristic of miniaturization, be not controlled effectively but distortion and heat are poor, image quality decreases, and camera lens overall length is also somewhat long, can also shorten again.

Utility model content

Therefore, the utility model proposes the interactive lens system of a kind of 3D, in the situation that meeting following lens combination setting, can ensure possess the advantage such as large aperture, miniaturization under wide-angle, high-resolution prerequisite, can effectively eliminate heat poor, distortion is carried out to good correction simultaneously.

The interactive camera lens of a kind of 3D, is extremely sequentially comprised as side by thing side: the first lens of the negative refracting power of tool, and its thing side is convex surface, is concave surface as side; The second lens of the positive refracting power of tool, it is convex surface as side; The 3rd lens of the negative refracting power of tool, it is concave surface as side; The 4th lens of the positive refracting power of tool, it is convex surface as side; The 5th lens of the negative refracting power of tool, its thing side is convex surface, is concave surface as side, and thing side is provided with a point of inflexion; Separately be provided with an aperture, be placed between first lens and the second lens.

In the interactive camera lens of the utility model 3D, five lens are all made of plastics, other the second lens can be separately by glass manufacture, same the 4th lens can be also separately glass manufacture, described second or the 4th lens adopt separately glass material, can effectively reduce the poor impact on camera lens of heat, make the imaging of lens system more stable, reliable, wherein, when the 4th lens adopt glass material, eliminate the poor effect optimum of heat.

The described configuration of first lens and the second lens, is conducive to the wide-angle characteristic of system, reduces the tolerance susceptibility of system simultaneously; Aperture is arranged between the second lens and the 3rd lens conventionally, but the utility model aperture is arranged between first lens and the second lens, resolving power that can Hoisting System.

The 5th paraxial place, lens thing side is convex surface, and periphery turns protruding by recessed, and as side, paraxial place is concave surface, and periphery transfers convex surface to, and special shape this bending, that have flex point can effectively be revised distortion, obtains better image quality.

In the interactive camera lens of the utility model 3D, R3, R4 are respectively the radius-of-curvature of the second He Xiang side, lens thing side, to meet following relationship: 0< (R3+R4)/(R3-R4) <1.2, the second lens meet above-mentioned requirements, be conducive to the wide-angle characteristic of system, and can reduce the tolerance susceptibility of system.

In the interactive camera lens of the utility model 3D, T12 is spacing distance on the axle of first lens and the second lens, T23 is spacing distance on the second lens and the 3rd axis of lens, to meet following relationship: 7<T12/T23<25, restriction by above relational expression to system, can ensure wide-angle and promote miniaturization.

In the interactive camera lens of the utility model 3D, f1, f2 are respectively the focal length of first lens and the second lens, to meet following relationship :-3.2<f1/f2<-1.4, first lens and second focal length of lens meet above formula requirement, can give prominence to the wide-angle characteristic of system.

In the interactive camera lens of the utility model 3D, f2 is the focal length of the second lens, f is the whole focal length of described lens combination, SD is that aperture to the five lens are as distance on the axle of side, TD is that first lens thing side to the five lens are as distance on the axle of side, meet following two relational expressions, meet following relationship: 0.8<f2/f<1.4,0.6<SD/TD<0.8, meet above relational expression, be conducive to the wide-angle characteristic of system, and can promote the miniaturization of camera lens and promote resolving power.

In the interactive camera lens of the utility model 3D, T12 is first lens and the spacing distance of the second lens on optical axis, T23 is the second lens and the spacing distance of the 3rd lens on optical axis, T34 is the 3rd lens and the spacing distance of the 4th lens on optical axis, T45 is the 4th lens and the spacing distance of the 5th lens on optical axis, TTL is the overall length of described lens system, meet following relationship: 0.2< (T12+T23+T34+T45)/TTL<0.4, reasonable and appropriate air distribution interval, improve the image quality of this optical system, shorten camera lens overall length.

In the interactive camera lens of the utility model 3D, ImgH is the half of effective pixel area diagonal line length on imaging surface, TTL is the overall length of described lens system, meet following relationship: 0.2<ImgH/TTL<0.4, above relational expression can allow camera lens keep the characteristic of miniaturization, so that be mounted on frivolous portable electronic product.

In the interactive camera lens of the utility model 3D, f1 is the focal length of first lens, f is the whole focal length of described lens combination, meet following relationship :-4<f1/f<-2, first lens meets above relational expression, can provide enough refracting powers to system, allow the utility model keep the characteristic of wide-angle simultaneously.

Preferably, in described camera lens, the second lens thing side is convex surface.Preferably, in described camera lens, the 3rd lens thing side is convex surface.Preferably, in described camera lens, the 4th lens thing side is convex surface.

The utility model has adopted 5 aspherical lens, by the distribution of different focal power and radius-of-curvature, rationally place aperture, distance between manipulative lens, breaks through the design of lens shape in the past, has overcome the defect of prior art, current specification requirement and performance requirement have been proposed to a kind of new solution, can ensure to possess the advantage such as large aperture, miniaturization under wide-angle, high-resolution prerequisite, effectively reduce heat poor simultaneously, distortion is being carried out to good correction.

Brief description of the drawings

Fig. 1 is the schematic diagram of the interactive camera lens embodiment 1 of the 3D that provides of the utility model;

Fig. 2,3,4,5 is respectively chromaticity difference diagram (mm) on the axle of embodiment 1, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Fig. 6 is the schematic diagram of the interactive camera lens embodiment 2 of the 3D that provides of the utility model;

Fig. 7,8,9,10 is respectively chromaticity difference diagram (mm) on the axle of embodiment 2, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 11 is the schematic diagram of the interactive camera lens embodiment 3 of the 3D that provides of the utility model;

Figure 12,13,14, the 15th, (%) schemed in chromaticity difference diagram on the axle of embodiment 3 (mm), astigmatism figure (mm), distortion, (μ is m) for ratio chromatism, figure;

Figure 16 is the schematic diagram of the interactive camera lens embodiment 4 of the 3D that provides of the utility model;

Figure 17,18,19,20 is respectively chromaticity difference diagram (mm) on the axle of embodiment 4, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 21 is the schematic diagram of the interactive camera lens embodiment 5 of the 3D that provides of the utility model;

Figure 22,23,24,25 is respectively chromaticity difference diagram (mm) on the axle of embodiment 5, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 26 is the schematic diagram of the interactive camera lens embodiment 6 of the 3D that provides of the utility model;

Figure 27,28,29,30 is respectively chromaticity difference diagram (mm) on the axle of embodiment 6, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 31 is the schematic diagram of the interactive camera lens embodiment 7 of the 3D that provides of the utility model;

Figure 32,33,34,35 is respectively chromaticity difference diagram (mm) on the axle of embodiment 7, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 36 is the schematic diagram of the interactive camera lens embodiment 8 of the 3D that provides of the utility model;

Figure 37,38,39,40 is respectively chromaticity difference diagram (mm) on the axle of embodiment 8, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 41 is the schematic diagram of the interactive camera lens embodiment 9 of the 3D that provides of the utility model;

Figure 42,43,44,45 is respectively chromaticity difference diagram (mm) on the axle of embodiment 9, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 46 is the schematic diagram of the interactive camera lens embodiment 10 of the 3D that provides of the utility model;

Figure 47,48,49,50 is respectively chromaticity difference diagram (mm) on the axle of embodiment 10, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure;

Figure 51 is the schematic diagram of the interactive camera lens embodiment 11 of the 3D that provides of the utility model;

Figure 52,53,54,55 is respectively chromaticity difference diagram (mm) on the axle of embodiment 11, astigmatism figure (mm), distortion figure (%), (μ m) for ratio chromatism, figure.

Embodiment

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Fig. 1 in embodiment 1: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described first lens E1 to the five lens E5 are all made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.53; F=1.32; F1=-2.69; F2=1.42; F3=-1.81; F4=1.27; F5=-2.89; (R3+R4)/(R3-R4)=0.36; F1/f2=-1.89;

T12/T23＝19.93；(T12+T23+T34+T45)/TTL＝0.28；f2/f＝1.07；

SD/TD＝0.65；ImgH/TTL＝0.26；f1/f＝-2.03；

Systematic parameter: f-number 1.6

Table one:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	300.0000		274.5937
1	Aspheric surface	2.9648	0.2492	F52R	1.1246	1.7563
							2	Aspheric surface	0.9433	0.9973		0.8008	0.1812
stop	Sphere	Infinite	-0.0029		0.5549
							4	Aspheric surface	2.2338	0.6316	F52R	0.6197	-3.4342
5	Aspheric surface	-1.0446	0.0499		0.7536	-0.4075

6	Aspheric surface	3.0615	0.2797	EP5000	0.8058	9.9839
							7	Aspheric surface	0.8094	0.0959		0.8615	-0.3116
8	Aspheric surface	2.2132	0.8578	F52R	0.8971	1.3126
							9	Aspheric surface	-0.8535	0.1196		0.9310	-0.4457
10	Aspheric surface	1.4466	0.3012	EP5000	0.9045	1.0586
							11	Aspheric surface	0.7464	0.3364		1.0032	-0.7965
12	Sphere	Infinite	0.2100	BK7	1.0477
							13	Sphere	Infinite	0.4045		1.0927
IMG	Sphere	Infinite			1.2052

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table two:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Fig. 6 in embodiment 2: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the 4th lens E4 is made up of glass, and other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.53; F=1.33; F1=-2.7; F2=1.42; F3=-2.04; F4=1.35; F5=-2.89; (R3+R4)/(R3-R4)=0.3; F1/f2=-1.9; T12/T23=19.93;

(T12+T23+T34+T45)/TTL＝0.28；f2/f＝1.07；SD/TD＝0.65；

ImgH/TTL＝0.3；f1/f＝-2.03；

Systematic parameter: f-number 1.6

Table three:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	300.0000		311.2960
1	Aspheric surface	2.9648	0.2492	F52R	1.1588	1.7563
							2	Aspheric surface	0.9433	0.9973		0.8161	0.1812
stop	Sphere	Infinite	-0.0029		0.5557
							4	Aspheric surface	1.9895	0.6999	F52R	0.6366	4.3827
5	Aspheric surface	-1.0830	0.0499		0.7857	-1.1873
							6	Aspheric surface	2.7995	0.2600	EP5000	0.8196	6.3013
7	Aspheric surface	0.8573	0.1088		0.8500	-0.1634
							8	Aspheric surface	3.1081	0.8130	D-ZK3_MELT	0.9491	4.8425
9	Aspheric surface	-0.9602	0.1196		0.9797	-0.0777
							10	Aspheric surface	1.4466	0.3012	EP5000	0.9542	1.0586
11	Aspheric surface	0.7464	0.3364		1.0910	-0.7965
							12	Sphere	Infinite	0.2100	BK7	1.1476
13	Sphere	Infinite	0.3867		1.2032
							IMG	Sphere	Infinite			1.3639

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table four:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 11 in embodiment 3: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the second lens E2 is made up of glass, and other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.59; F=1.33; F1=-2.69; F2=1.82; F3=-2.53; F4=1.24; F5=-2.77; (R3+R4)/(R3-R4)=0.27; F1/f2=-1.48;

T12/T23＝8.98；(T12+T23+T34+T45)/TTL＝0.29；f2/f＝1.37；

SD/TD＝0.66；ImgH/TTL＝0.26；f1/f＝-2.03；

Systematic parameter: f-number 1.6

Table five:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	300.0000		273.5869
1	Aspheric surface	2.9648	0.2492	F52R	1.1250	1.7563
							2	Aspheric surface	0.9433	0.9973		0.8015	0.1812
stop	Sphere	Infinite	-0.0029		0.5572
							4	Aspheric surface	2.7811	0.6670	D-ZK3_MELT	0.6110	-131.3845
5	Aspheric surface	-1.5854	0.1108		0.7733	-0.7454
							6	Aspheric surface	1.7765	0.2797	EP5000	0.8313	-34.3483
7	Aspheric surface	0.7958	0.0768		0.8733	-0.7352
							8	Aspheric surface	1.7186	0.8442	F52R	0.9200	-2.7342
9	Aspheric surface	-0.8936	0.1314		0.9450	-0.3720
							10	Aspheric surface	1.4634	0.2959	EP5000	0.9018	1.0855
11	Aspheric surface	0.7382	0.3364		1.0005	-0.7965
							12	Sphere	Infinite	0.2100	BK7	1.0438
13	Sphere	Infinite	0.3891		1.0908
							IMG	Sphere	Infinite			1.2027

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table six:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 16 in embodiment 4: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side concave surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the second lens E2 is made up of glass, and all the other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.42; F=1.3; F1=-5.1; F2=1.59; F3=-2.16; F4=1.29; F5=-2.61; (R3+R4)/(R3-R4)=1.17; F1/f2=-3.197;

T12/T23＝22.29；(T12+T23+T34+T45)/TTL＝0.3；f2/f＝1.22；

SD/TD＝0.71；ImgH/TTL＝0.27；f1/f＝-3.92；

Systematic parameter: f-number 1.68

Table seven:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	325.4607		307.9664
1	Aspheric surface	1.7486	0.1978	F52R	0.9946	-0.2510
							2	Aspheric surface	1.0247	0.8974		0.8032	0.3785
stop	Sphere	Infinite	0.1137		0.4398
							4	Aspheric surface	-10.9841	0.6561	D-ZK3_MELT	0.5026	-24.0357
5	Aspheric surface	-0.8822	0.0454		0.7188	-1.0132
							6	Aspheric surface	2.2125	0.3798	EP5000	0.8640	-46.0296
7	Aspheric surface	0.7946	0.1067		1.0062	-0.8319
							8	Aspheric surface	2.3355	0.9374	F52R	1.0309	0.5519
9	Aspheric surface	-0.8446	0.1847		1.0385	-0.4090
							10	Aspheric surface	1.0819	0.2749	EP5000	0.9449	0.0435
11	Aspheric surface	0.5914	0.3029		1.1303	-1.2164
							12	Sphere	Infinite	0.2278	BK7	1.1536
13	Sphere	Infinite	0.0967		1.1841
							IMG	Sphere	Infinite			1.2039

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table eight:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 21 in embodiment 5: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side concave surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the second lens E2 is made up of glass, and all the other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=5.07; F=1.3; F1=-3.41; F2=1.46; F3=-1.88; F4=1.38; F5=-2.51; (R3+R4)/(R3-R4)=0.29; F1/f2=-2.33;

T12/T23＝11.75；(T12+T23+T34+T45)/TTL＝0.33；f2/f＝1.13；

SD/TD＝0.62；ImgH/TTL＝0.24；f1/f＝-2.62；

Systematic parameter: f-number 1.74

Table nine:

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table ten:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 26 in embodiment 6: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side concave surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the second lens E2 is made up of glass, and all the other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.7; F=1.55; F1=-3.98; F2=1.28; F3=-2.22; F4=1.79; F5=-3.11; (R3+R4)/(R3-R4)=0.44; F1/f2=-3.11; T12/T23=12.12;

(T12+T23+T34+T45)/TTL＝0.33；f2/f＝0.82；SD/TD＝0.63；

ImgH/TTL＝0.26；f1/f＝-2.57；

Systematic parameter: f-number 1.66

Table ten one:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	322.9254		233.6505
1	Aspheric surface	2.3207	0.2243	F52R	1.0515	1.6502
							2	Aspheric surface	1.0750	1.1340		0.7932	0.2307
stop	Sphere	Infinite	-0.0068		0.5829
							4	Aspheric surface	2.4994	0.6772	D-ZK3_MELT	0.5980	-232.8882
5	Aspheric surface	-0.9658	0.0930		0.7461	-5.3601
							6	Aspheric surface	8.2774	0.2664	EP5000	0.7773	38.1496
7	Aspheric surface	1.1978	0.1777		0.8096	-0.5518
							8	Aspheric surface	-13.8559	0.6776	F52R	0.8375	-305.6832
9	Aspheric surface	-0.9161	0.1355		0.8722	-0.3495

10	Aspheric surface	1.7885	0.2667	EP5000	0.8427	0.4413
							11	Aspheric surface	0.8877	0.6237		0.9962	-0.7288
12	Sphere	Infinite	0.2260	BK7	1.1329
							13	Sphere	Infinite	0.2036		1.1660
IMG	Sphere	Infinite			1.2281

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table ten two:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 31 in embodiment 7: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described five lens are all made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.69; F=1.57; F1=-3.72; F2=1.49; F3=-1.82; F4=1.3; F5=-2.62; (R3+R4)/(R3-R4)=0.57; F1/f2=-2.5; T12/T23=17.18;

(T12+T23+T34+T45)/TTL＝0.25；f2/f＝0.95；SD/TD＝0.66；

ImgH/TTL＝0.26；f1/f＝-2.37；

Systematic parameter: f-number 1.6

Table ten three:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	300.0000		234.1344
1	Aspheric surface	2.3105	0.3391	F52R	1.1069	1.6269
							2	Aspheric surface	1.0157	0.9271		0.7958	0.2139
stop	Sphere	Infinite	-0.0029		0.5881
							4	Aspheric surface	3.5665	0.6156	F52R	0.6281	-0.6971
5	Aspheric surface	-0.9661	0.0538		0.7677	-0.4074
							6	Aspheric surface	3.0845	0.3316	EP5000	0.8470	10.2015
7	Aspheric surface	0.8092	0.0844		0.9347	-0.3133
							8	Aspheric surface	2.2818	0.9997	F52R	0.9586	1.4402
9	Aspheric surface	-0.8551	0.1033		0.9750	-0.4447
							10	Aspheric surface	1.4724	0.2843	EP5000	0.9510	1.0846
11	Aspheric surface	0.7251	0.3438		1.0777	-0.8317
							12	Sphere	Infinite	0.2100	BK7	1.1333
13	Sphere	Infinite	0.4045		1.1750
							IMG	Sphere	Infinite			1.2745

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table ten four:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 36 in embodiment 8: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the second lens E2 is made up of glass, and all the other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=3.85; F=1.3; F1=-4.81; F2=1.56; F3=-2.21; F4=1.25; F5=-2.69; (R3+R4)/(R3-R4)=0.77; F1/f2=-3.08; T12/T23=13.06;

(T12+T23+T34+T45)/TTL＝0.28；f2/f＝1.2；SD/TD＝0.73；

ImgH/TTL＝0.31；f1/f＝-3.71；

Systematic parameter: f-number 1.68

Table ten five:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	325.4607		294.3094
1	Aspheric surface	1.7157	0.2009	F52R	0.8765	-0.2871
							2	Aspheric surface	0.9886	0.6797		0.6887	0.4179
stop	Sphere	Infinite	0.0657		0.4246
							4	Aspheric surface	7.6503	0.6462	D-ZK3_MELT	0.4785	-167.1235
5	Aspheric surface	-1.0092	0.0571		0.6791	-1.0295
							6	Aspheric surface	2.1611	0.3220	EP5000	0.7812	-45.8562
7	Aspheric surface	0.8043	0.0815		0.8571	-0.8370

8	Aspheric surface	2.2115	0.6916	F52R	0.8693	0.5610
							9	Aspheric surface	-0.8583	0.1832		0.8848	-0.4153
10	Aspheric surface	1.0860	0.2794	EP5000	0.8376	-0.0275
							11	Aspheric surface	0.5995	0.3151		1.0270	-1.3155
12	Sphere	Infinite	0.2278	BK7	1.0768
							13	Sphere	Infinite	0.0967		1.1655
IMG	Sphere	Infinite			1.2288

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table ten six:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 41 in embodiment 9: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the second lens E2 is made up of glass, and all the other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.29; F=1.31; F1=-4.82; F2=1.57; F3=-2.18; F4=1.29; F5=-2.64; (R3+R4)/(R3-R4)=0.88; F1/f2=-3.07; T12/T23=24.31;

(T12+T23+T34+T45)/TTL＝0.29；f2/f＝1.2；SD/TD＝0.73；

ImgH/TTL＝0.28；f1/f＝-3.69；

Systematic parameter: f-number 1.68

Table ten seven:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	325.4607		290.5048
1	Aspheric surface	1.7654	0.2006	F52R	0.9154	-0.3322
							2	Aspheric surface	1.0074	0.7755		0.7251	0.4072
stop	Sphere	Infinite	0.1620		0.4353
							4	Aspheric surface	14.7192	0.6543	D-ZK3_MELT	0.5462	-469.1618
5	Aspheric surface	-0.9654	0.0383		0.7464	-1.0608
							6	Aspheric surface	2.1850	0.3864	EP5000	0.8767	-48.1600
7	Aspheric surface	0.7939	0.0865		0.9733	-0.8285
							8	Aspheric surface	2.2711	0.9059	F52R	0.9847	0.4725
9	Aspheric surface	-0.8544	0.1777		0.9940	-0.4108
							10	Aspheric surface	1.0844	0.2736	EP5000	0.8949	0.0376
11	Aspheric surface	0.5953	0.3073		1.0317	-1.2853
							12	Sphere	Infinite	0.2278	BK7	1.0645
13	Sphere	Infinite	0.0967		1.1360
							IMG	Sphere	Infinite			1.2189

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table ten eight:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 46 in embodiment 10: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side concave surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described the second lens E2 is made up of glass, and all the other four lens are made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.39; F=1.27; F1=-4.83; F2=1.55; F3=-2.15; F4=1.29; F5=-2.62; (R3+R4)/(R3-R4)=1.07; F1/f2=-3.12; T12/T23=24.49;

(T12+T23+T34+T45)/TTL＝0.3；f2/f＝1.22；SD/TD＝0.71；

ImgH/TTL＝0.27；f1/f＝-3.81；

Systematic parameter: f-number 1.68

Table ten nine:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	325.4607		313.7605
1	Aspheric surface	1.8033	0.1992	F52R	0.9909	-0.2782
							2	Aspheric surface	1.0229	0.8831		0.7904	0.3783
stop	Sphere	Infinite	0.1213		0.4319
							4	Aspheric surface	-26.3678	0.6595	D-ZK3_MELT	0.5066	119.1316
5	Aspheric surface	-0.8889	0.0410		0.7200	-1.0277

6	Aspheric surface	2.2085	0.3611	EP5000	0.8564	-46.7081
							7	Aspheric surface	0.7942	0.1063		0.9898	-0.8307
8	Aspheric surface	2.3392	0.9365	F52R	1.0152	0.5287
							9	Aspheric surface	-0.8449	0.1843		1.0267	-0.4094
10	Aspheric surface	1.0825	0.2764	EP5000	0.9409	0.0422
							11	Aspheric surface	0.5927	0.2976		1.1287	-1.2222
12	Sphere	Infinite	0.2278	BK7	1.1527
							13	Sphere	Infinite	0.0967		1.1845
IMG	Sphere	Infinite			1.2051

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table two ten:

The optical lens that the utility model provides is sequentially from the object side to the image side as shown in Figure 55 in embodiment 11: first lens E1, aperture, the second lens E2, the 3rd lens E3, the 4th lens E4, the 5th lens E5, optical filter E6 and imaging surface.Described first lens E1 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The second lens E2 has negative refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 3rd lens E3 has positive refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface; The 4th lens E4 has positive refracting power, thing side convex surface, and as side convex surface, He Xiang side, thing side is aspheric surface; The 5th lens E5 has negative refracting power, thing side convex surface, and as side concave surface, He Xiang side, thing side is aspheric surface, and its thing side is provided with a point of inflexion; Described first lens to the five lens are all made of plastics.

From object space to image space, described first lens E1 two sides is S1, S2, aperture face is S3, the second lens E2 two sides is S4, S5, the 3rd lens E3 two sides is S6, S7, and the 4th lens E4 two sides is S8, S9, and the 5th lens E5 two sides is S10, S11, optical filter E6 two sides is S12, S13, and optical imagery face is S14.

The each parameter of its camera lens is as described below: TTL=4.59; F=1.1; F1=-1.55; F2=1.32; F3=-1.88; F4=1.34; F5=-3.79; (R3+R4)/(R3-R4)=0.1; F1/f2=-1.73; T12/T23=7.01;

(T12+T23+T34+T45)/TTL＝0.34；f2/f＝1.2；SD/TD＝0.61；

ImgH/TTL＝0.24；f1/f＝--2.08；

Systematic parameter: f-number 1.6

Table two 11:

Surface number	Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
							obj	Sphere	Infinite	Infinite
1	Aspheric surface	2.9656	0.3525	F52R	1.2629	3.0544
							2	Aspheric surface	0.8330	1.2275		0.8017	-0.1093
stop	Sphere	Infinite	-0.0621		0.5151
							4	Aspheric surface	1.4478	0.6342	F52R	0.5747	-0.1693
5	Aspheric surface	-1.1817	0.1663		0.6597	-0.2894
							6	Aspheric surface	3.1238	0.2598	EP5000	0.6888	-5.5652
7	Aspheric surface	0.8411	0.1009		0.7895	-0.0787
							8	Aspheric surface	2.0084	0.7398	F52R	0.8477	-3.9642
9	Aspheric surface	-0.9753	0.1365		0.8676	0.0392
							10	Aspheric surface	2.1081	0.4448	EP5000	0.8506	4.7772
11	Aspheric surface	1.0354	0.3144		1.0176	-0.1405
							12	Sphere	Infinite	0.2100	BK7	1.0907
13	Sphere	Infinite	0.0615		1.1594
							IMG	Sphere	Infinite			1.1832

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, the A16 of non-spherical lens:

Table two 12:

By chromaticity difference diagram, astigmatism figure, distortion figure and ratio chromatism, figure on the axle of each embodiment, can find out and the utlity model has good optical property.

Although described principle of the present utility model and embodiment for micro pick-up lens above; but under above-mentioned instruction of the present utility model; those skilled in the art can carry out various improvement and distortion on the basis of above-described embodiment, and these improvement or distortion all drop in protection domain of the present utility model.It will be understood by those skilled in the art that specific descriptions are above in order to explain the purpose of this utility model, and not for limiting the utility model, protection domain of the present utility model is limited by claim and equivalent thereof.

Claims (11)

1. the interactive camera lens of 3D, is characterized in that: extremely sequentially comprised as side by thing side:

The first lens of the negative refracting power of tool, its thing side is convex surface, is concave surface as side;

The second lens of the positive refracting power of tool, it is convex surface as side;

The 3rd lens of the negative refracting power of tool, it is concave surface as side;

The 4th lens of the positive refracting power of tool, it is convex surface as side;

The 5th lens of the negative refracting power of tool, its thing side is convex surface, is concave surface as side, and thing side is provided with a point of inflexion;

Separately be provided with an aperture, be placed between first lens and the second lens;

Described camera lens meets:

0<(R3+R4)/(R3-R4)<1.2；

7<T12/T23<25；

Wherein, R3, R4 are respectively the radius-of-curvature of the second He Xiang side, lens thing side, and T12 is the spacing on optical axis of first lens and the second lens, and T23 is the second lens and the spacing of the 3rd lens on optical axis.

2. the interactive camera lens of 3D according to claim 1, is characterized in that, described camera lens meets: 0.8<f2/f<1.4,0.6<SD/TD<0.8

Wherein, f2 is the focal length of the second lens, the whole focal length that f is described lens combination, SD be aperture to the five lens as distance on the axle of side, TD is that first lens thing side to the five lens are as distance on the axle of side.

3. the interactive camera lens of 3D according to claim 2, is characterized in that, described the second lens are made up of glass.

4. the interactive camera lens of 3D according to claim 2, is characterized in that, described the 4th lens are made up of glass.

5. according to claim 1,2,3, the interactive camera lens of 4 arbitrary described 3D, it is characterized in that: in described camera lens, the second lens thing side is convex surface.

6. the interactive camera lens of 3D according to claim 5, is characterized in that: in described camera lens, the 3rd lens thing side is convex surface.

7. the interactive camera lens of 3D according to claim 6, is characterized in that: in described camera lens, the 4th lens thing side is convex surface.

8. according to claim 1,2,3,4, the interactive camera lens of 7 arbitrary described 3D, it is characterized in that, described camera lens meets :-3.2<f1/f2<-1.4

Wherein, f1, f2 are respectively the focal length of first lens and the second lens.

9. according to claim 1,2,3,4, the interactive camera lens of 7 arbitrary described 3D, it is characterized in that, described camera lens meets :-4<f1/f<-2

Wherein, the focal length that f1 is first lens, the whole focal length that f is described lens combination.

10. according to claim 1,2,3,4, the interactive camera lens of 7 arbitrary described 3D, it is characterized in that, described camera lens meets:

0.2<(T12+T23+T34+T45)/TTL<0.4

Wherein, T12 is first lens and the spacing distance of the second lens on optical axis, T23 is the second lens and the spacing distance of the 3rd lens on optical axis, T34 is the 3rd lens and the spacing distance of the 4th lens on optical axis, T45 is the 4th lens and the spacing distance of the 5th lens on optical axis, the overall length that TTL is described lens system.

11. according to the interactive camera lens of arbitrary described 3D in claim 1,2,3,4,7, it is characterized in that, described camera lens meets: 0.2<ImgH/TTL<0.4

Wherein, ImgH is the half of effective pixel area diagonal line length on imaging surface, the overall length that TTL is described lens system.