CN204188868U

CN204188868U - A kind of wide-angle lens

Info

Publication number: CN204188868U
Application number: CN201420545914.1U
Authority: CN
Inventors: 杨春
Original assignee: Qingdao Goertek Co Ltd
Current assignee: Qingdao Goertek Co Ltd
Priority date: 2014-09-22
Filing date: 2014-09-22
Publication date: 2015-03-04
Anticipated expiration: 2024-09-22

Abstract

The utility model provides a kind of wide-angle lens, comprises successively along light direction: front group and rear group, and described front group comprises the first negative lens and the second positive lens, and rear group comprises a similar balsaming lens group: the 3rd positive lens and the 4th negative lens.Concrete: the first negative lens has the convex first surface to object space and the recessed second surface to image space, is positioned at the top of camera lens; Described second positive lens has recessed the 3rd surface to object space and convex the 4th surface to image space; Described 3rd positive lens has convex surperficial and convex in image space the 6th surface to the 5th of object space; Described 4th negative lens has recessed the 7th surface to object space and recessed the 8th surface to image space.According to the Rational Arrangement between each element, lens thickness and airspace thickness are impartial, and lens shape is easy to processing and shaping, to meet while distortion requirement is eliminated at Large visual angle angle and optimize the quality of high/low temperature imaging and correct, in addition with low cost, the simple miniaturization of structure.

Description

A kind of wide-angle lens

Technical field

The utility model relates to optical lens design field, particularly relates to a kind of wide-angle lens.

Background technology

Along with the progress of technology, consumer electronics product requires also more and more higher to the application of wide-angle lens, especially at various different environment: as under the rugged surroundings such as snow mountain, high temperature, higher to the expectation of showing before camera, well-known high/low temperature can produce very large rear Jiao's skew to the camera lens of general plastic construction, thus can affect the quality of imaging, and serious meeting causes image blur, the situation of systematic parameter instability, causes the generation of the failure modes such as camera lens cisco unity malfunction.

The main method of elimination thermal migration conventional is at present by using a large amount of glass materials, vary with temperature very little due to glass materials refractive index so can be good at eliminating temperature to the impact of system focal length, but use in batch production the wide-angle lens of glass material first come cost relatively high, two come to be that distortion is difficult to be corrected in desirable scope, if use Glass aspheric cost and production capacity can the versatility of limit product and widespread adoption greatly.

The problem that with high costs, distortion how to avoid the thermal migration because using plastic material eyeglass to bring and use glass mirror to bring are difficult to correct becomes the difficult problem that needs overcome.

Utility model content

The purpose of this utility model is to provide a kind of wide-angle lens, solves the problem at least in part, and can eliminate the problem that the thermal migration phenomenon brought because of material cause and distortion be difficult to correct while reducing camera lens cost, being applicable to batch production.

The utility model provides a kind of wide-angle lens, comprise successively along light direction: organize before diaphragm and group after diaphragm, before described diaphragm, group comprises the first negative lens and the second positive lens, after institute's diaphragm, group comprises the 3rd positive lens and the 4th negative lens, and the 3rd positive lens and the 4th negative lens form a similar gummed group;

Described first negative lens has the convex first surface to object space and the recessed second surface to image space, is positioned at the top of camera lens;

Described second positive lens has recessed the 3rd surface to object space and convex the 4th surface to image space;

Described 3rd positive lens has convex the 5th surface to object space and convex the 6th surface to image space;

Described 4th negative lens has recessed the 7th surface to object space and recessed the 8th surface to image space.

Further, described wide-angle lens also includes aperture diaphragm, and described aperture diaphragm is between described second positive lens and described 3rd positive lens.

Further, the overall length of getting described whole arrangement of mirrors sheet is ttl, and effective focal length is f, and wherein the center thickness of the first eyeglass is T1, and the clearance of the first eyeglass and the second eyeglass is T12, and above parameter meets following formula:

4<ttl/f<6.5；

0<T1/ttl<0.15；

0.5<T12/f<1.5 and

0.1<T1/f<0.3。

Further, the focal length getting the first positive lens is the focal length of f1 and the 4th negative lens is meet following relational expression between f4, f1 and f4:

0.5<f4/f1<1 and

-3.0<f1/f<-1.9。

Further, the focal length that the focal length getting the first negative lens is f1, the focal length of the second positive lens is f2, the focal length of the 3rd positive lens is f3 and the 4th negative lens is f4; Following relational expression is met between f1, f2, f3 and f4:

f3>-f4>-f1>f2。

Further, described first positive lens, the second positive lens and the 4th negative lens adopt the eyeglass of plastic material, and it is with low cost, and advantageously in elimination distortion; Described 3rd positive lens adopts the eyeglass of glass material, for correcting the thermal migration phenomenon that temperature causes lens imaging.

Further, 7th surface and the 8th surface of the 3rd surface of the first surface of described first positive lens and second surface, the second positive lens and the 4th surface and the 4th negative lens are aspheric surface, its surperficial radian of aspherical lens is different from common spheric glass, the curved surface of eyeglass is just needed to change in order to pursue eyeglass thinness, and adopted spherical design in the past, the aberration made and distortion increase, the bad phenomenon such as result occurs that obvious image is unclear, and visual field is distorted, the visual field is narrow and small; Aspheric design, have modified image, solves the problems such as visual field distortion, meanwhile, make eyeglass gentlier, thinner, more flat; And, still keep excellent shock resistance, wearer is used safely; 5th surface of the 3rd lens and the 6th surface are sphere, for correcting thermal migration phenomenon, effectively compensation temperature can offset the focal length variations produced.

Further, described wide-angle lens is also provided with cutoff filter in the image side of the 4th negative lens, and optionally, described cutoff filter adopts the glass material of BK7 model, and can cross the light that IR cut film plating process carrys out filtering infrared band.

Further, the refractive index of described first negative lens and dispersion range are 1.5 < n ₁< 1.6,50 < v ₁< 60; The refractive index of the second positive lens and dispersion range are 1.5 < n ₂< 1.6,50 < v ₂< 60; The refractive index of the 3rd positive lens and dispersion range are 1.5 < n ₃< 1.7,50 < v ₃< 65; The refractive index of the 4th negative lens and dispersion range are 1.6 < n ₄< 1.7,20 < v ₄< 30.

Further, described aspheric surface adopts even aspherical equation to design, and even asphericity coefficient meets following equation:

z = \frac{{CY}^{2}}{1 + \sqrt{1 - (1 + k) C^{2} Y^{2}}} + Σ_{i = 2}^{N} α_{i} Y^{2 i}

Wherein, z is the coordinate along optical axis direction, and Y is the radial coordinate in units of length of lens unit, and C is curvature (1/R), k is circular cone coefficient (Coin Constant), α _ibe the coefficient of each high-order term, 2i is aspheric high power (the order of Aspherical Coefficient), and optionally, i=8 and quadratic term are up to 16 powers.

Further, described aspheric surface can also adopt odd aspherical equation to design, and the general formula of odd aspherical equation is as follows:

z = \frac{{CY}^{2}}{1 + \sqrt{1 - (1 + k) C^{2} Y^{2}}} + Σ_{i = 1}^{N} β_{i} Y^{i}

Wherein, i=1,2,3,4 ... N, equally also can reach purpose of design.

The camera lens comprising the utility model and provide of this enforcement adopts four eyeglasses, and be plastic aspherical element eyeglass, from the above, the wide-angle lens that the utility model provides has following characteristics:

1, except the 3rd positive lens adopts glass material eyeglass, all the other eyeglasses all adopt plastic material eyeglass, compare glass material, and plastic material has that quality is light, cost is low, be easy to the advantages such as machine-shaping, the production cost of wide-angle lens is significantly reduced, is suitable for producing in enormous quantities;

2, the optical surface of the first negative lens, the second positive lens and the 4th negative lens all adopts aspheric surface, effectively can control aberration, aspheric mirror edge is thinner, centre light and marginal ray can focus on same position, can effectively reduce spherical aberration, improve the relative aperture of system, expand field angle, and then improving the image quality of wide-angle lens under low-light (level) environment, tolerance is good, and can improve optical property by adjustment asphericity coefficient;

3, wide-angle lens distribution type is reasonable, adopt positive and negative lens combination, first negative lens carries out high angle scattered light collection, effective bending axis outer visual field chief ray, its angle relative to optical axis and bore are diminished, and then reduce the size of rear set of pieces, thereafter the divergent rays that the second positive lens makes the first negative lens produce again becomes parallel rays through converging and passes through aperture diaphragm, what organize lens set employing after system aperture diaphragm is general optical collection system, wherein organizing the 3rd positive lens is afterwards glass material eyeglass, there is larger focal power contribution, thermal migration can be corrected, the focal length variations that effective compensation temperature skew produces, the effect of rear group of the 3rd positive lens and the 4th negative lens is positive and negative lens combination color difference eliminating, and make final light collection in image planes.

4, wide-angle lens structure four eyeglasses are according to the Rational Arrangement between each element, lens shape be easy to processing and shaping, meet Large visual angle angle to eliminate while distortion requires and optimize the quality of high/low temperature imaging and correct, its structure simply in addition, reaches camera lens miniaturization object;

Accompanying drawing explanation

Fig. 1 is the wide-angle lens structural representation of the utility model embodiment one;

Fig. 2 is the MTF transfer curve figure of the utility model embodiment one under limiting resolution;

Fig. 3 is the MTF transfer curve figure of the utility model embodiment one under 1/2 limiting resolution;

Fig. 4 is the optical field diagram of the utility model embodiment one;

Fig. 5 is the optical distortion figure of the utility model embodiment one;

Fig. 6 is the point range figure of the utility model embodiment one;

Fig. 7 is the chromatic curve figure of the utility model embodiment one;

Fig. 8 is the relative luminance curve figure of the utility model embodiment one;

Fig. 9-11 is the MTF transfer curve figure of the utility model embodiment one respectively at-10 DEG C, 20 DEG C and 50 DEG C respectively.

Reference numeral: L1, the first negative lens, L2, the second positive lens, L3, the 3rd positive lens; L4, the 4th negative lens, S1, first surface, S2, second surface; S3, the 3rd surface, S4, the 4th surface, S5, the 5th surface; S6, the 6th surface; S7, the 7th surface, S8, the 8th surface, A, diaphragm; F cutoff filter, G, chip cover glass.

Embodiment

In order to be illustrated more clearly in the utility model embodiment or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.

Embodiment one

Please refer to the wide-angle lens structural representation of the utility model embodiment one shown in Fig. 1, comprise successively along light direction: front group and rear group, described front group comprises the first negative lens L1 and the second positive lens L2, rear group comprises a similar balsaming lens group: the 3rd positive lens L3 and the 4th negative lens L4, concrete: the first negative lens L1 has the convex first surface S1 to object space and the recessed second surface S2 to image space, is positioned at the top of camera lens;

Described second positive lens L2 has recessed the 3rd surperficial S3 to object space and convex the 4th surperficial S4 to image space;

Described 3rd positive lens L3 has convex the 5th surperficial S5 to object space and convex in the surperficial S6 of image space the 6th;

Described 4th negative lens L4 has recessed the 7th surperficial S7 to object space and recessed the 8th surperficial S8 to image space.

The overall length of getting described whole arrangement of mirrors sheet is ttl, and effective focal length is f, and wherein the center thickness of the first eyeglass is T1, and the clearance of the first eyeglass and the second eyeglass is T12, and above parameter meets following formula:

4<ttl/f<6.5；

0<T1/ttl<0.15；

0.5<T12/f<1.5 and

0.1<T1/f<0.3。

The focal length that the focal length getting the first negative lens L1 is f1, the focal length of the second positive lens L2 is f2, the focal length of the 3rd positive lens L3 is f3 and the 4th negative lens L4 is f4; Following relational expression is met between f1, f2, f3 and f4:

f3>-f4>-f1>f2；

0.5<f4/f1<1 and

-3.0<f1/f<-1.9。

Described wide-angle lens also includes aperture diaphragm A, and described aperture diaphragm A is between described second positive lens L2 and described 3rd positive lens L3.

Described first positive lens, the second positive lens L2 and the 4th negative lens L4 adopt the eyeglass of plastic material, and described 3rd positive lens L3 adopts the eyeglass of glass material.

7th surperficial S7 and the 8th surperficial S8 of the 3rd surperficial S3 of the first surface S1 of described first positive lens and second surface S2, the second positive lens L2 and the 4th surperficial S4 and the 4th negative lens L4 are aspheric surface, and the 5th surperficial S5 and the 6th surperficial S6 of the 3rd lens are sphere.

Described wide-angle lens is also provided with cutoff filter F in the image side of the 4th negative lens L4, described cutoff filter F adopts the glass material of BK7 model, its refractive index and dispersion are respectively n=1.5168, and v=64.17 also can cross the light that IR cut film plating process carrys out filtering infrared band.

The image side of described cutoff filter F is also provided with chip cover glass G, and described cutoff filter F adopts the glass material of BK7 model, for the protection of sensitive chip.

Described first negative lens L1 adopts the plastic material eyeglass of E48R model, and its refractive index and dispersion are respectively n ₁=1.53, v ₁=56; Second positive lens L2 adopts E48R plastic material eyeglass, and its refractive index and dispersion are respectively n2=1.53, v2=56; 3rd positive lens L3 adopts the glass material of ZK7 model, and its refractive index and dispersion are respectively n3=1.61, v3=60.7; 4th negative lens L4 adopts the plastic material of SP3810 model, and its refractive index and dispersion are respectively n4=1.64, v4=23.3.

Table 1 is the system structure parameter of a kind of wide-angle lens in the utility model embodiment.As shown in table 1, show respectively:

The optical surface (Surface) of sequentially numbering along light direction, comprises successively: the 5th surperficial S5 of the 3rd surperficial S3 of the first surface S1 of the first negative lens L1, the second surface S2 of the first negative lens L1, the second positive lens L2, the 4th surperficial S4 of the second positive lens L2, the 3rd positive lens L3, the 6th surperficial S6 of the 3rd positive lens L3, the 7th surperficial S7 of the 4th negative lens L4, the 8th surperficial S8 of the 4th negative lens L4, cutoff filter F, imager chip, wherein: surface type (Type), the curvature (C) of each optical surface on optical axis, along the thickness (T) on the optical axis in light direction between each optical surface and adjacent next optical surface, along the material (Glass) on the optical axis in light direction between each optical surface and adjacent next optical surface, half bore (Semi-Diameter), circular cone coefficient (Conic), focal power (Focal power), wherein, the unit of thickness (T) and half bore (Semi-Diameter) is mm, the unit of curvature (C) and focal power (Focal power) is mm ^-1.

Table 2 is aspherical surface datas of a kind of wide-angle lens in an embodiment, on the basis of table 1, and the even asphericity coefficient α of each optical surface ₂, α ₃, α ₄, α ₅, α ₆, α ₇, α ₈as shown in table 2, wherein aspheric

z = \frac{{CY}^{2}}{1 + \sqrt{1 - (1 + k) C^{2} Y^{2}}} + Σ_{i = 2}^{N} α_{i} Y^{2 i}

Face coefficient can meet following equation:

In the present embodiment, i=8 and quadratic term are up to 16 powers, and z is the coordinate along optical axis direction, and Y is the radial coordinate in units of length of lens unit, and C is curvature (1/R), k is circular cone coefficient (Coin Constant), α _ibe the coefficient of each high-order term, 2i is aspheric high power (the order of Aspherical Coefficient), adopts aspheric design, have modified image, solves the problems such as visual field distortion, meanwhile, make eyeglass gentlier, thinner, more flat.And, still keep excellent shock resistance, wearer is used safely.

Table 1

surface	Type	Curvature	Thickness	Glass	Semi-Diameter	Conic	focal power
								S1	EVENASPH	0.2713	0.6000	E48R	3.1695	-0.2848	-0.2132
S2	EVENASPH	0.7115	2.5477		2.1507	-0.8680
								S3	EVENASPH	0.0133	3.8650	E48R	1.7704	0.0000	0.1533
S4	EVENASPH	-0.2790	-0.2115		1.2725	-5.5280
								A	STANDARD	0.0000	0.5388		1.2468	0.0000
S5	STANDARD	0.3435	1.8230	ZK7	1.6279	0.0000	0.3422
								S6	STANDARD	-0.2791	0.0651		1.5622	0.0000
S7	EVENASPH	-0.3660	0.4807	SP3810	1.4949	-13.8335	-0.2606
								S8	EVENASPH	0.0348	0.7000		1.4112	301.7874
10	STANDARD	0.0000	0.3000	BK7	1.5597	0.0000
								11	STANDARD	0.0000	1.8000		1.6321	0.0000
12	STANDARD	0.0000	0.4000	BK7	2.3253	0.0000
								13	STANDARD	0.0000	0.0415		2.4236	0.0000
14	STANDARD	0.0000	0.0000		2.4198	0.0000

surface

α ₂

α ₃

α ₄

α ₅

α ₆

α ₇

α ₈

S1

-6.64E-03

-4.66E-04

5.48E-05

2.06E-07

-1.65E-07

-9.61E-09

8.76E-10

S2

9.18E-03

-2.49E-03

2.70E-04

-1.03E-04

6.37E-06

5.11E-06

-1.07E-06

S3

-7.62E-03

-9.76E-04

-1.92E-04

-1.14E-04

2.13E-05

7.73E-06

-2.50E-06

S4

-1.34E-02

-8.77E-04

2.65E-03

-1.11E-03

-2.00E-04

2.91E-04

-6.16E-05

A

0.00E+00

S5

0.00E+00

S6

0.00E+00

S7

1.69E-02

-1.17E-02

-9.93E-04

9.56E-04

-1.16E-05

-6.49E-05

7.76E-06

S8

1.17E-01

-3.62E-02

6.38E-03

1.43E-03

-6.46E-04

-1.83E-04

7.45E-05

10

0.00E+00

11

0.00E+00

12

0.00E+00

13

0.00E+00

14

0.00E+00

As shown in Table 1, the utility model embodiment one wide-angle lens overall length is less than 13mm.

Described wide-angle lens coordinates OV9714 chip to achieve 85 degree of field angle, and distortion is controlled within 1%.

The transport function of described wide-angle lens in every millimeter of situation, reaches more than 0.35 at limiting resolution 166 line within 0.8 visual field.

The focal length 2.47mm of described wide-angle lens, camera lens F number is 2.0, coordinates CMOS pixel dimension to be 3um, Diagonal Dimension 4.528mm, cutoff frequency 166lp/mm (line is to every millimeter).

The utility model embodiment one realizes visible light wave range (430nm-650nm) blur-free imaging, without obvious thermal migration.

Correspond ground, we also can adopt odd aspherical equation to design, and the general formula of odd aspherical equation is as follows:

z = \frac{{CY}^{2}}{1 + \sqrt{1 - (1 + k) C^{2} Y^{2}}} + Σ_{i = 1}^{N} β_{i} Y^{i}

Wherein, z is the coordinate along optical axis direction, and Y is the radial coordinate in units of length of lens unit, and C is curvature (1/R), k is circular cone coefficient, β _ibe the coefficient of each high-order term, i is aspheric high power, i=1,2,3,4 ... N equally also can reach purpose of design.

Please refer to the MTF transfer curve figure of the utility model embodiment one under limiting resolution as shown in Figure 2, MTF transfer curve figure (optical transfer function) can the image quality of concentrated expression system, its curve shape is more level and smooth, and X-axis height is higher relatively, the image quality of proof system is better, Fig. 2 reflection be MTF curve under sensor limit resolution, known according to figure, under sensor limit resolution, the MTF curve of wide-angle lens is comparatively smoothly compact, more than 0.35 is reached within 166 lines are to every millimeter and 0.8 visual field, the mtf value characterized is very high, show that the aberration of the present embodiment wide-angle lens has obtained good correction.

Please refer to the utility model embodiment one MTF curve map under 1/2 limit differentiates frequency as shown in Figure 3, due to optical lens imaging and paraxial optics (Paraxial Optics in real work, Gaussian optics) result that obtains is different, have certain departing from, the relative paraxial imagery of optical imagery depart from title aberration.Can be obtained by Fig. 3, the aberration of the present embodiment wide-angle lens under 1/2 limiting resolution obtains well-corrected equally.

Please refer to the optical field diagram of the utility model embodiment one as shown in Figure 4, different curve represents different wavelength, right side graph is meridian direction, leftmost curve is for being Sagittal field curvature, the two does the astigmatism that difference is exactly system, astigmatism and the curvature of field are the important aberrations affecting the outer field rays of axle, astigmatism crosses the image quality of the serious system that the has influence on off-axis ray of conference, the curvature of field can cause center and peripheral optimal imaging not in one plane, and from figure, the curvature of field of system and astigmatism are all corrected within 100um.

Please refer to the distortion curve that curve as shown in Figure 5 is the present embodiment one wide-angle lens, distortion can not affect the sharpness of wide-angle lens, but the anamorphose of system can be caused, for camera lens, correcting distorted to be sample be difficulty, the optical distortion of native system is less than 1%, and this illustrates that distortion has been remedied to an extraordinary degree.

Please refer to the point range figure of the utility model embodiment one as shown in Figure 6, with reference to figure due to point range figure show be camera lens each field rays image planes place converge and formation picture, each picture is exactly a disc of confusion, two discs of confusion are distinguished near rear being just not easy, therefore the resolution of camera lens is just limited, therefore disc of confusion is larger, illustrate that the resolution of camera lens is lower, so it characterizes the characteristic that camera lens obtains various aberration, the disc of confusion RMS radius of point range figure is less, proves that the image quality of camera lens is better.The disc of confusion RMS diameter of this camera lens is all less than 4um, and illustrate at visible light wave range, camera lens aberration correction is good.

Please refer to the chromatic curve figure of the utility model embodiment one shown in Fig. 7, aberration is also known as chromatic aberation, and be a major defect of lens imaging, aberration is exactly the difference of color in simple terms, occurs in polychromatic light when being light source.Known according to figure, the wide-angle lens aberration that the present embodiment provides, within 5um, shows that its Difference Control is good.

Please refer to the relative luminance curve figure of the utility model embodiment one shown in Fig. 8, relative brightness refers to the brightness ratio along optical axis field angle and full filed angle on imaging plane, the i.e. diagonal corners brightness of image sensor and the ratio of central brightness, according to picture, the relative brightness of the present embodiment one wide-angle lens reaches more than 45%, show that system can have good performance under low-light (level), image quality meets the demands.

Please refer to the MTF transfer curve figure of the utility model embodiment one shown in Fig. 9-11 respectively at-10 DEG C, 20 DEG C and 50 DEG C; in the low temperature environment of-10 DEG C; in hot environment in the home of 20 DEG C and at 50 DEG C; can find out that the MTF curve of the utility model embodiment one wide-angle lens does not significantly worsen substantially; both the thermal migration impact that temperature causes camera lens had been avoided; corrected again distortion, image quality is good under various circumstances.

The camera lens that this enforcement provides adopts four eyeglasses, is plastic aspherical element eyeglass, and from the above, the wide-angle lens that the utility model provides has following characteristics:

1, except the 3rd positive lens, all the other eyeglasses all adopt plastic material eyeglass, and plastic material has that quality is light, cost is low, be easy to the advantages such as machine-shaping, and the production cost of wide-angle lens is significantly reduced, and are suitable for producing in enormous quantities;

2, the optical surface of the first negative lens L1, the second positive lens L2 and the 4th negative lens L4 all adopts aspheric surface, effectively can control aberration, aspheric mirror edge is thinner, centre light and marginal ray can focus on same position, can effectively reduce spherical aberration, improve the relative aperture of system, expand field angle, and then improving the image quality of wide-angle lens under low-light (level) environment, tolerance is good, and can improve optical property by adjustment asphericity coefficient;

3, wide-angle lens distribution type is reasonable, adopt positive and negative lens combination, first negative lens L1 carries out high angle scattered light collection, effective bending axis outer visual field chief ray, its angle relative to optical axis and bore are diminished, and then reduce the size of rear set of pieces, thereafter the divergent rays that the second positive lens L2 makes the first negative lens L1 produce becomes parallel rays and by aperture diaphragm A again through converging, what organize lens set employing after system aperture diaphragm A is general optical collection system, wherein organizing the 3rd positive lens L3 is afterwards glass material eyeglass, there is larger focal power contribution, thermal migration can be corrected, the focal length variations that effective compensation temperature skew produces, the effect of rear group of the 3rd positive lens L3 and the 4th negative lens L4 is positive and negative lens combination color difference eliminating, and make final light collection in image planes,

4, wide-angle lens structure four eyeglasses are according to the Rational Arrangement between each element,, lens shape be easy to processing and shaping, meet Large visual angle angle eliminate distortion requirement while and the quality of high/low temperature imaging is optimized and corrects, in addition its structure is simple, reaches camera lens miniaturization object.

Obviously, those skilled in the art can carry out various change and modification to utility model and not depart from spirit and scope of the present utility model.Like this, if these amendments of the present utility model and modification belong within the scope of the utility model claim and equivalent technologies thereof, then the utility model is also intended to comprise these change and modification.

Claims

1. a wide-angle lens, comprises front group and rear group successively along light direction, described front group comprises the first negative lens and the second positive lens, and rear group comprises the 3rd positive lens and the 4th negative lens, it is characterized in that:

2. wide-angle lens according to claim 1, it is characterized in that: the overall length of described whole arrangement of mirrors sheet is ttl, and effective focal length is f, and wherein the center thickness of the first eyeglass is T1, the clearance of the first eyeglass and the second eyeglass is T12, and above parameter meets following formula:

4<ttl/f<6.5；

0<T1/ttl<0.15；

0.5<T12/f<1.5 and

0.1<T1/f<0.3。

3. wide-angle lens according to claim 1, is characterized in that: the focal length that the focal length of the first negative lens is f1, the focal length of the second positive lens is f2, the focal length of the 3rd positive lens is f3 and the 4th negative lens is f4; Following relational expression is met between f1, f2, f3 and f4:

f3>-f4>-f1>f2；

0.5<f4/f1<1 and

-3.0<f1/f<-1.9。

4. the wide-angle lens according to any one of claim 1-3, is characterized in that: described wide-angle lens also includes aperture diaphragm, and described aperture diaphragm is between described second positive lens and described 3rd positive lens.

5. the wide-angle lens according to any one of claim 1-3, is characterized in that: described first positive lens, the second positive lens and the 4th negative lens adopt the eyeglass of plastic material, and described 3rd positive lens adopts the eyeglass of glass material.

6. wide-angle lens according to claim 5, is characterized in that:

The refractive index n of described first negative lens and the scope of dispersion v meet respectively: 1.5 < n ₁< 1.6,50 < v ₁< 60;

The refractive index n of described second positive lens and the scope of dispersion v meet respectively: 1.5 < n ₂< 1.6,50 < v ₂< 60;

The described refractive index n of the 3rd positive lens and the scope of dispersion v meet respectively: 1.5 < n ₃< 1.7,50 < v ₃< 65;

The described refractive index n of the 4th negative lens and the scope of dispersion v meet respectively: 1.6 < n ₄< 1.7,20 < v ₄< 30.

7. wide-angle lens according to claim 6, is characterized in that: described first negative lens adopts the plastic material eyeglass of E48R model, and its refractive index n and dispersion v is respectively n ₁=1.53, v ₁=56; Second positive lens adopts E48R plastic material eyeglass, and its refractive index n and dispersion v is respectively n2=1.53, v2=56; 3rd positive lens adopts the glass material of ZK7 model, and its refractive index n and dispersion v is respectively n3=1.61, v3=60.7; 4th negative lens adopts the plastic material of SP3810 model, and its refractive index n and dispersion v is respectively n4=1.64, v4=23.3.

8. the wide-angle lens according to any one of claim 1-3, it is characterized in that: the 7th surface and the 8th surface of the 3rd surface of the first surface of described first positive lens and second surface, the second positive lens and the 4th surface and the 4th negative lens are aspheric surface, and the 5th surface of the 3rd lens and the 6th surface are sphere.

9. wide-angle lens according to claim 8, is characterized in that: described aspheric surface adopts even aspherical equation to design, and even asphericity coefficient meets following equation:

Wherein, z is the coordinate along optical axis direction, and Y is the radial coordinate in units of length of lens unit, and C is curvature (1/R), k is circular cone coefficient, α _ibe the coefficient of each high-order term, 2i is aspheric high power.

10. the wide-angle lens according to Claim 8 described in item, is characterized in that: described aspherical lens can also adopt odd aspherical equation to design, and the general formula of odd aspherical equation is as follows:

Wherein, z is the coordinate along optical axis direction, and Y is the radial coordinate in units of length of lens unit, and C is curvature (1/R), k is circular cone coefficient, β _ibe the coefficient of each high-order term, i is aspheric high power.