CN201837770U - Near infrared wide-angle lens - Google Patents

Abstract

The utility model discloses a near infrared wide-angle lens which comprises six groups of lenses arranged along an optical axis from an objective space to an image space, wherein the first lens, the second lens and the sixth lens are lenses with negative focal power, the third lens, the fourth lens and the fifth lens are lenses with positive focal power, at least one group of lens of the first lens and the second lens is non-spherical lens, the first lens is a meniscus lens with a convex surface facing to the objective space, the second lens is the meniscus lens with the convex surface facing to the image space, a concave surface of the first lens faces to that of the second lens, and an optical filter is arranged between the third lens and the fourth lens. Through the design, imaging quality can be met at an angle of large aperture and a large field of view, the problems of large distortion and low resolution in the near infrared wide-angle lens are solved, and the near infrared wide-angle lens has better technical effect.

Description

A kind of near infrared wide-angle lens

Technical field

The utility model relates to a kind of wide-angle lens, specifically, relates to a kind of high-resolution near infrared wide-angle lens of mainly being made up of six groups of lens.

Background technology

Along with the development of camera lens technology, the application of wide-angle lens more and more is extensive.

Wide-angle lens claims short-focus lens again, is that the focal distance ratio standard lens is short, the camera lens that field angle is big.In general, occasion that it is mainly used and target are that what to pursue is that field of view angle is high as much as possible, simultaneously, wish that again image can be undistorted as much as possible, wish that especially distortion in images can lack as much as possible.

But, the application of existing wide-angle lens is comparatively narrow, it can't be used under the dark condition of light, the method that addresses this problem is that traditional wide-angle lens is made the near infrared wide-angle lens, generally be that an optical filter is set in the rear end of overall lens group, thereby play the effect of optical filtering, reach normal imaging effect whereby.This kind near infrared wide-angle lens has been widely used among various video cameras and the game machine.

But this design also has some shortcomings: at first, be the problem of the image quality of this lens, we know that the incident angle of camera lens is big more, and the phenomenon of distortion produces serious more, therefore, take usually the distortion aberration of the camera lens of design bigger; The second, because on designing usually, above-mentioned optical filter is arranged on the side of overall lens group near the imaging side mostly, therefore, when carrying out imaging, the light that incides the camera lens the inside is easy to generate wavelength shift, thereby cause the brightness of imaging not enough, and then influence the optical effect of whole lens imaging.

The utility model content

Technical purpose of the present utility model is to overcome the shortcoming of near infrared wide-angle lens in the prior art, a kind of novel near infrared wide-angle lens is provided, it is little that this near infrared wide-angle lens has the big distortion of field of view angle, and, brightness of image, the higher technological merit of image quality.

In order to realize above-mentioned technical purpose, the utility model is realized by following technical scheme:

A kind of near infrared wide-angle lens, comprise along optical axis six groups of lens from the object side to the image side, wherein, first, second, the 6th lens are the lens with negative power, three, the 4th, the 5th lens are the lens with positive light coke, and having one group of lens at least among described first, second lens is non-spherical lenses.

Further, preferred construction is, described first lens are meniscus shaped lenses, and convex surface is towards object space; Second lens are meniscus shaped lenses, and convex surface is towards picture side; The concave surface of first lens is towards the concave surface of second lens.

Further, preferred construction is that described the 3rd lens, the 4th lens are lenticular lens; The 5th lens are falcate eyeglasses, and convex surface is towards picture side.

Further, preferred construction is that described the 4th lens are non-spherical lenses.

Further, preferred construction is, described the 6th lens are non-spherical lenses, and it is arc lens, and the center convex surface is towards object space.

Further, preferred construction is, also comprises optical filter, and described optical filter is arranged between the 3rd lens and the 4th lens.

Further, preferred construction is that the diaphragm of described camera lens is arranged between the 3rd lens and the 4th lens.

Further, preferred construction is, described first lens, and second lens satisfy following expression formula:

-1＜f1，2/f＜-0.01

In the formula, f1,2 is combined focal lengths of first lens, second lens;

F represents the focal length of whole camera lens lens combination.

Further, preferred construction is that described the 4th lens satisfy following expression formula:

0.15＜f4/f＜1

In the formula, f4 is the focal length of the 4th lens;

F represents the focal length of whole camera lens lens combination.

Further, preferred construction is that described lens are universal focus lens groups fixing and that cannot move.

The utility model because first or second lens have been taked the non-spherical lens technology, can improve field of view angle significantly after having taked above scheme, reduce distortion, thereby can increase the imaging effect of wide-angle lens significantly; And under imaging len, take non-spherical lens, can reduce the chief ray incident angle, thereby have better technical effect.

In addition, optical filter is placed between the 3rd lens, the 4th lens of lens, can reduces the incident angle of light significantly, prevent wavelength shift and cause the problem of brightness.

In addition, the utility model makes it satisfy specific optical relation formula by focal power is regulated, and guarantees to satisfy image quality under the angle of wide-aperture visual angle, and therefore, with respect to prior art, it has better technical effect.

Description of drawings

By the description of its exemplary embodiment being carried out below in conjunction with accompanying drawing, the above-mentioned feature and advantage of the utility model will become apparent and understand easily.

Fig. 1 is the concrete structure synoptic diagram of the related near infrared wide-angle lens of the utility model;

Fig. 2 is that the axle of the related near infrared wide-angle lens of the utility model is gone up chromaticity difference diagram;

Fig. 3 is the astigmatism figure of the related near infrared wide-angle lens of the utility model;

Fig. 4 is the distortion figure of the related near infrared wide-angle lens of the utility model;

The ratio chromatism, figure of the near infrared wide-angle lens that Fig. 5 the utility model is related.

Embodiment

Below in conjunction with accompanying drawing the utility model is described in further detail.

Fig. 1 is the concrete structure synoptic diagram of the utility model near infrared wide-angle lens.

As shown in the figure, near infrared wide-angle lens of the present utility model mainly comprises six groups of lens, along optical axis be successively from the object side to the image side: the first lens E1, the second lens E2 with negative power, the 3rd lens E3, the 4th lens E4, the 5th lens E5 with positive focal power, and, the 6th lens E6 with negative power, and each lens are positioned at above the same optical axis.

Wherein, the first lens E1 or the second lens E2 have at least one to be non-spherical lens.

The characteristics of non-spherical lens are: is continually varying from the lens center to peripheral curvature.Different with the spherical lens that certain curvature is arranged from the lens center to the periphery, non-spherical lens has better radius-of-curvature characteristic, has to improve the advantage of distorting aberration and improving astigmatic image error, can make the visual field become bigger and true.After adopting non-spherical lens, can eliminate the aberration that in imaging, occurs as much as possible, thereby improve image quality.

Specifically among the utility model, the first lens E1 or the second lens E2 choose non-spherical lens, promptly utilize non-spherical lens good optical spy to, guarantee in the overall lens imaging, can receive the light of focal power incident in a big way as much as possible, and, by means of the above-mentioned advantage of non-spherical lens, overcome the more shortcoming of aberration when adopting spherical lens, keep the optical imagery quality of overall lens.

Among specific embodiment, we select the first lens E1 and the second lens E2 to adopt non-spherical lens, can improve image quality better and reduce the distortion in images phenomenon.

In this preferred specific embodiment, the first lens E1 chooses a meniscus shaped lens, and the convex surface of lens is towards object space; The second lens E2 chooses meniscus shaped lens, and the convex surface of lens is towards picture side; Above the integral body, the concave surface of first lens is towards the concave surface of second lens.

By this kind design, the light of overall lens enters among the lens with comparalive ease, thereby can improve field of view angle further.

Among this lens combination, chief ray passes through converge to imaging plane, and described the 3rd lens E3, the 4th lens E4 to be lenticular lens after the 3rd lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6; The 5th lens E5 is the falcate eyeglass, and convex surface is towards picture side.

Among preferred embodiment, the 6th lens E6 chooses non-spherical lens, and, choose the arc lens of being shaped as of the 6th lens E6, the center convex surface is towards object space.

Because the effect of the 6th lens E6 is arranged on one side near picture side, adopt aspheric surface, arc lens, can proofread and correct the light path of whole incident ray preferably, thereby reduce the incident angle of chief ray, whereby, reach the reduction systematical distortion by reducing the chief ray incident angle, and then reach the technique effect that the distortion that makes whole lens combination drops to minimum.

In the preferred embodiment, the 4th lens E4 chooses non-spherical lens.

In addition, in order to overcome the brightness problem of traditional optical filter to imaging, among the utility model, we are arranged on optical filter E7 between the 3rd lens E3 and the 4th lens E4, and diaphragm E8 also is arranged between the 3rd lens E3 and the 4th lens E4, and, diaphragm E8 is arranged between optical filter E7 and the 4th lens E4, and the angle that diaphragm E8 and optical filter E7 are separated by is very near.

By this kind design, we can rely on the design of diaphragm E8 and optical filter E7, reduce the incident angle of the chief ray of overall lens, thereby, eliminate because of the wavelength shift of light with comparalive ease and cause various brightness problem, improve the optical quality of whole imaging.

In order to improve the imaging effect of whole set of shots, we need carry out specific design to some eyeglass, make it satisfy specific expression formula, to reach better optical effect.

Among the embodiment, the described first lens E1, the second lens E2 satisfies following expression formula:

-1＜f1，f2/f＜-0.01

In the formula, f1, f2 are the combined focal lengths of first lens, second lens;

F represents the focal length of whole camera lens lens combination.

Satisfy after the above-mentioned expression formula, can guarantee the angle with great visual angle of overall optical system.

In another embodiment, described the 4th lens satisfy following expression formula:

0.15＜f4/f＜1

In the formula, f4 is the focal length of the 4th lens;

F represents the focal length of whole camera lens lens combination.

Satisfied after the above-mentioned expression formula, can guarantee that overall optical system under wide-aperture situation, improves image quality significantly.

Be described below with reference to the technique effect of chart, so that above-mentioned feature and advantage of the present utility model are clear more and understanding easily above-mentioned utility model.

Among this embodiment, it is the lens of fixed focal length, and each lens set stationkeeping is not removable.

And among this specific embodiment, the concrete parameter of each lens is as follows:

f1＝-7.905；f2＝-10.706；f3＝9.243；f4＝7.566；f5＝16.378；f6＝-1395.1；f1，2＝-3.88；f＝21.496。

What table 1, table 2 were listed is the correlation parameter of lens, comprises surface type, the radius-of-curvature of lens face, also has thickness, material, effective diameter and the circular cone coefficient of each lens.Wherein, table 2 is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, A16 of non-spherical lens:

We are parallel from object space one side along optical axis; with each lens number consecutively, the minute surface of the first lens E1 is S1, S2, and the minute surface of the second lens E2 is S3, S4; the minute surface of the 3rd lens E3 is S5, S6; the minute surface of optical filter E7 is S7, S8, and the face of diaphragm is S9, and the minute surface of the 4th lens is S10, S11; the minute surface of the 5th lens is S12, S13; the minute surface of the 6th lens E6 is S14, S15, and the minute surface of chip cover glass E9 is S16, S17, and the face of image planes is S18.

Systematic parameter: 1/3 " sensor devices f-number 1.2

Table 1

Face sequence number S	Surface type	Radius of curvature R	Thickness D	Material	Effective diameter D	The circular cone COEFFICIENT K
							Object plane	Sphere	Infinite	1500		3010.16
S1	Aspheric surface	4.9458	1.0299	1.585/29.9	9.80	-0.3615
							S2	Aspheric surface	2.1809	4.1104		6.55	-1.0336
S3	Aspheric surface	-4.1658	1.1729	1.585/29.9	6.60	-0.9619
							S4	Aspheric surface	-14.4301	1.0433		6.30	1.4928
S5	Sphere	22.6670	1.7303	1.847/23.8	6.40
							S6	Sphere	-10.9930	1.6944		6.52
S7	Sphere	Infinite	0.55	1.517/64.2	6.33
							S8	Sphere	Infinite		0		6.30
S9	Sphere	Infinite	0.1088		6.28
							S10	Aspheric surface	4.9770	2.3356	1.531/54.0	6.40	-0.7125
S11	Aspheric surface	-16.3651	2.595		6.20	-16.2826
							S12	Aspheric surface	-12.3895	1.3676	1.531/54.0	5.10	10.2450
S13	Aspheric surface	-5.2635	0.1		5.49	-7.5648

S14	Aspheric surface	25.6003	0.9979	1.585/29.9	5.40	-68.1668
							S15	Aspheric surface	24.4515	1.5602		5.69	-296.8453
S16	Sphere	Infinite	0.75	1.517/64.2	6.40
							S17	Sphere	Infinite	0.35		6.40
S18	Sphere	Infinite			6.06

Table 2

The face sequence number

A4

A6

A8

A10

A12

A14

A16

S1

-2.6030E-03

1.0203E-04

-4.0623E-06

6.5862E-08

S2

1.3984E-03

4.0769E-05

1.8060E-05

-1.4988E-06

S3

-5.6820E-03

5.3231E-04

-1.0507E-05

6.1770E-07

-3.9751E-08

S4

-2.5315E-03

5.3535E-04

-2.4402E-05

1.4677E-06

-3.4154E-08

S10

-6.3086E-04

4.1823E-05

-9.6712E-09

8.7837E-09

S11

-9.9794E-04

2.9146E-05

2.1646E-06

-1.0583E-07

S12

-3.0462E-03

-3.6656E-04

-5.5471E-06

5.9209E-07

S13

-4.9039E-03

-2.9686E-04

2.2255E-05

-5.9406E-07

S14

-9.3911E-03

-3.5704E-04

7.0558E-05

-1.1134E-06

S15

-8.9683E-03

4.0169E-04

6.7412E-06

9.5382E-08

In addition, Fig. 2 to Fig. 5 is the optical performance curve figure corresponding to specific embodiment.Wherein, Fig. 2 is that the axle of the related near infrared wide-angle lens of expression the utility model is gone up chromaticity difference diagram, and the meeting focus point of the light of its expression different wave length after via optical system departs from, and unit is mm;

Fig. 3 is the astigmatism curve map of the related near infrared wide-angle lens of expression the utility model, the crooked and sagittal image surface bending of its expression meridianal image surface, and unit is mm;

Fig. 4 is the distortion figure of the related near infrared wide-angle lens of expression the utility model, the distortion sizes values under the expression different visual angles situation, and unit is %;

Fig. 5 is the ratio chromatism, figure of the related near infrared wide-angle lens of expression the utility model, the light of its expression different wave length via optical system after the deviation of different image heights on imaging plane, unit is μ m.

Data from above-mentioned optical performance curve figure can be analyzed discovery, and the utility model near infrared wide-angle lens has optical effect preferably.

It should be noted that, concrete parameter in the above table only is exemplary, and the value of each lens composition radius-of-curvature, face interval and refractive index etc. are not limited to the shown value by above-mentioned each numerical value embodiment, other value can be adopted, the similar techniques effect can be reached.

Though described principle of the present utility model and embodiment at the near infrared wide-angle 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 the foregoing description, and these improvement or distortion drop in the protection domain of the present utility model.It will be understood by those skilled in the art that top specific descriptions just in order to explain the purpose of this utility model, are not to be used to limit the utility model.Protection domain of the present utility model is limited by claim and equivalent thereof.

Claims (10)

1. near infrared wide-angle lens, comprise along optical axis six groups of lens from the object side to the image side, wherein, first, second, the 6th lens are the lens with negative power, three, the 4th, the 5th lens are the lens with positive light coke, and having one group of lens at least among described first, second lens is non-spherical lenses.

2. near infrared wide-angle lens according to claim 1 is characterized in that, described first lens are meniscus shaped lenses, and convex surface is towards object space; Second lens are meniscus shaped lenses, and convex surface is towards picture side; The concave surface of first lens is towards the concave surface of second lens.

3. near infrared wide-angle lens according to claim 1 is characterized in that, described the 3rd lens, the 4th lens are lenticular lens; The 5th lens are falcate eyeglasses, and convex surface is towards picture side.

4. near infrared wide-angle lens according to claim 3 is characterized in that, described the 4th lens are non-spherical lenses.

5. near infrared wide-angle lens according to claim 1 is characterized in that, described the 6th lens are non-spherical lenses, and it is arc lens, and the center convex surface is towards object space.

6. near infrared wide-angle lens according to claim 1 is characterized in that, also comprises optical filter, and described optical filter is arranged between the 3rd lens and the 4th lens.

7. near infrared wide-angle lens according to claim 6 is characterized in that, the diaphragm of described camera lens is arranged between the 3rd lens and the 4th lens.

8. near infrared wide-angle lens according to claim 1 is characterized in that, described first lens, and second lens satisfy following expression formula:

-1＜f1，2/f＜-0.01

In the formula, f1,2 is combined focal lengths of first lens, second lens;

F represents the focal length of whole camera lens lens combination.

9. near infrared wide-angle lens according to claim 1 is characterized in that, described the 4th lens satisfy following expression formula:

0.15＜f4/f＜1

In the formula, f4 is the focal length of the 4th lens;

F represents the focal length of whole camera lens lens combination.

10. according to the arbitrary described near infrared wide-angle lens of claim 1～9, it is characterized in that described lens are universal focus lens groups fixing and that cannot move.

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