CN208477187U - Imaging lens - Google Patents
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- CN208477187U CN208477187U CN201820842143.0U CN201820842143U CN208477187U CN 208477187 U CN208477187 U CN 208477187U CN 201820842143 U CN201820842143 U CN 201820842143U CN 208477187 U CN208477187 U CN 208477187U
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Abstract
This application discloses a kind of imaging lens, which sequentially includes: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens by object side to image side along optical axis.First lens have positive light coke;Second lens have negative power, and object side and image side surface are concave surface;The third lens have positive light coke, and image side surface is convex surface;4th lens have negative power, and object side is concave surface;5th lens and the 6th lens all have positive light coke or negative power.The half ImgH of total effective focal length f of imaging lens and the effective pixel area diagonal line length on the imaging surface of imaging lens meets 2.0≤f/ImgH≤3.0.
Description
Technical field
This application involves a kind of imaging lens, more specifically, this application involves a kind of imaging lens including six-element lens.
Background technique
On the one hand, with charge coupled device (Charge-Coupled Device, CCD) and complementary metal-oxide half
The performance of the imaging sensors such as conductor (Complementary Metal-Oxide Semiconductor, CMOS) improves and ruler
Very little reduction, high image quality and miniaturization for the pick-up lens used that matches propose corresponding requirements.On the other hand, with
The lightening development trend of the portable electronic products such as mobile phone, tablet computer, it is also desirable to matching used pick-up lens becomes
It is thinner, volume is smaller.
In order to meet small form factor requirements, need to be reduced as far as the number of lenses of imaging lens, but reduce number of lenses
It will cause the shortage of lens design freedom degree, so that camera lens is difficult to meet the needs of high imaging performance.In addition, most at present
Pick-up lens is all made of wide-angle optics to obtain the image of wide viewing angle, but camera lens is made to be unfavorable for shooting compared with far object,
Clearly image can not be obtained.
Currently rise it is double take the photograph technology, telephoto lens and wide-angle lens has been used in combination, so as to pass through telephoto lens
High space angular resolution is obtained, then by image fusion technology, realizes high-frequency information enhancing.But taken the photograph in camera lens in this pair,
It is particularly critical for the design of telephoto lens, in particular for enabling the telephoto lens to meet focal length and ultrathin special simultaneously
Property.
Utility model content
This application provides be applicable to portable electronic product, can at least solve or part solve it is in the prior art
The imaging lens of at least one above-mentioned disadvantage, for example, telephoto lens.
On the one hand, this application provides such a imaging lens, which can sequentially be wrapped along optical axis by object side to image side
It includes: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.First lens can have positive light
Focal power;Second lens can have negative power, and object side and image side surface can be concave surface;The third lens can have positive light focus
Degree, image side surface can be convex surface;4th lens can have negative power, and object side can be concave surface;5th lens and the 6th are thoroughly
Mirror all has positive light coke or negative power.Wherein, having on total effective focal length f of imaging lens and the imaging surface of imaging lens
The half ImgH of effect pixel region diagonal line length can meet 2.0≤f/ImgH≤3.0.
In one embodiment, total effective focal length f of imaging lens and the second lens and the third lens are on optical axis
Spacing distance T23 can meet 8 < f/T23 < 12.
In one embodiment, the combined focal length f12 and the first lens of the first lens and the second lens are on optical axis
Center thickness CT1 can meet 3 < f12/CT1 < 4.5.
In one embodiment, spacing distance T45, the 5th lens and of the 4th lens and the 5th lens on optical axis
The interval of two lens of arbitrary neighborhood on optical axis into the 6th lens spacing distance T56 and first lens of six lens on optical axis
The summation ∑ AT of distance can meet 0.5≤(T45+T56)/∑ AT < 0.9.
In one embodiment, the curvature of the image side surface of the radius of curvature R 5 and the 4th lens of the object side of the third lens
Radius R8 can meet -1.5 < R5/R8 < -0.5.
In one embodiment, the curvature of the object side of the radius of curvature R 6 and the 4th lens of the image side surface of the third lens
Radius R7 can meet 0 < R6/R7 < 1.0.
In one embodiment, total effective focal length f of imaging lens and the effective focal length f3 of the third lens can meet 0.6
F/f3≤1.0 <.
In one embodiment, total effective focal length f of the imaging lens and effective focal length f4 of the 4th lens can meet-
1.5 < f/f4 < -1.0.
In one embodiment, total effective focal length f of imaging lens, the object side of the 5th lens radius of curvature R 9 with
The radius of curvature R 10 of the image side surface of 5th lens can meet | f/R9 |+| f/R10 | < 1.2.
In one embodiment, total effective focal length f of imaging lens, the object side of the 6th lens radius of curvature R 11
With the radius of curvature R 12 of the image side surface of the 6th lens can meet 0.5≤| f/R11 |+| f/R12 | < 1.5.
In one embodiment, the effective focal length f5 and the 6th lens of total effective focal length f of imaging lens, the 5th lens
Effective focal length f6 can meet 0.5≤| f/f5 |+| f/f6 | < 1.0.
In one embodiment, the radius of curvature R 2 of the image side surface of total effective focal length f and the first lens of imaging lens
- 1.0 < f/R2 < 0 can be met.
In one embodiment, total effective focal length f of imaging lens and the Entry pupil diameters EPD of imaging lens can meet f/
EPD < 2.5.
On the other hand, this application provides such a imaging lens, which sequentially may be used along optical axis by object side to image side
It include: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.First lens can have just
Focal power;Second lens can have negative power, and object side and image side surface can be concave surface;The third lens can have positive light focus
Degree, image side surface can be convex surface;4th lens can have negative power, and object side can be concave surface;5th lens and the 6th are thoroughly
Mirror all has positive light coke or negative power.Wherein, total effective focal length f of imaging lens, the 5th lens effective focal length f5 with
The effective focal length f6 of 6th lens can meet 0.5≤| f/f5 |+| f/f6 | < 1.0.
Another aspect, this application provides such a imaging lens, which sequentially may be used along optical axis by object side to image side
It include: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.First lens can have just
Focal power;Second lens can have negative power, and object side and image side surface can be concave surface;The third lens can have positive light focus
Degree, image side surface can be convex surface;4th lens can have negative power, and object side can be concave surface;5th lens and the 6th are thoroughly
Mirror all has positive light coke or negative power.Wherein, the combined focal length f12 and the first lens of the first lens and the second lens are in light
Center thickness CT1 on axis can meet 3 < f12/CT1 < 4.5.
Another aspect, this application provides such a imaging lens, which sequentially may be used along optical axis by object side to image side
It include: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.First lens can have just
Focal power;Second lens can have negative power, and object side and image side surface can be concave surface;The third lens can have positive light focus
Degree, image side surface can be convex surface;4th lens can have negative power, and object side can be concave surface;5th lens and the 6th are thoroughly
Mirror all has positive light coke or negative power.Wherein, the image side of the radius of curvature R 5 of the object side of the third lens and the 4th lens
The radius of curvature R 8 in face can meet -1.5 < R5/R8 < -0.5.
Another aspect, this application provides such a imaging lens, which sequentially may be used along optical axis by object side to image side
It include: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.First lens can have just
Focal power;Second lens can have negative power, and object side and image side surface can be concave surface;The third lens can have positive light focus
Degree, image side surface can be convex surface;4th lens can have negative power, and object side can be concave surface;5th lens and the 6th are thoroughly
Mirror all has positive light coke or negative power.Wherein, the object side of the radius of curvature R 6 of the image side surface of the third lens and the 4th lens
The radius of curvature R 7 in face can meet 0 < R6/R7 < 1.0.
Another aspect, this application provides such a imaging lens, which sequentially may be used along optical axis by object side to image side
It include: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.First lens can have just
Focal power;Second lens can have negative power, and object side and image side surface can be concave surface;The third lens can have positive light focus
Degree, image side surface can be convex surface;4th lens can have negative power, and object side can be concave surface;5th lens and the 6th are thoroughly
Mirror all has positive light coke or negative power.Wherein, total effective focal length f of imaging lens, the object side of the 5th lens curvature
Radius R9 and the radius of curvature R 10 of the image side surface of the 5th lens can meet | f/R9 |+| f/R10 | < 1.2.
Another aspect, this application provides such a imaging lens, which sequentially may be used along optical axis by object side to image side
It include: the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.First lens can have just
Focal power;Second lens can have negative power, and object side and image side surface can be concave surface;The third lens can have positive light focus
Degree, image side surface can be convex surface;4th lens can have negative power, and object side can be concave surface;5th lens and the 6th are thoroughly
Mirror all has positive light coke or negative power.Wherein, total effective focal length f of imaging lens, the object side of the 6th lens curvature
The radius of curvature R 12 of the image side surface of radius R11 and the 6th lens can meet 0.5≤| f/R11 |+| f/R12 | < 1.5.
The application uses multi-disc (for example, six) lens, by each power of lens of reasonable distribution, face type, each
Spacing etc. on axis between the center thickness of mirror and each lens, so that above-mentioned imaging lens have miniaturization, long-focus, Gao Cheng
As quality, can be at least one beneficial effect such as high-resolution chip matched well.
Detailed description of the invention
In conjunction with attached drawing, by the detailed description of following non-limiting embodiment, other features of the application, purpose and excellent
Point will be apparent.In the accompanying drawings:
Fig. 1 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 1;
Fig. 2A to Fig. 2 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 1, astigmatism curve and distortion
Curve;
Fig. 3 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 2;
Fig. 4 A to Fig. 4 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 2, astigmatism curve and distortion
Curve;
Fig. 5 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 3;
Fig. 6 A to Fig. 6 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 3, astigmatism curve and distortion
Curve;
Fig. 7 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 4;
Fig. 8 A to Fig. 8 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 4, astigmatism curve and distortion
Curve;
Fig. 9 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 5;
Figure 10 A to Figure 10 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 5, astigmatism curve and abnormal
Varied curve;
Figure 11 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 6;
Figure 12 A to figure 12 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 6, astigmatism curve and abnormal
Varied curve;
Figure 13 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 7;
Figure 14 A to Figure 14 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 7, astigmatism curve and abnormal
Varied curve;
Figure 15 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 8;
Figure 16 A to Figure 16 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 8, astigmatism curve and abnormal
Varied curve;
Figure 17 shows the structural schematic diagrams according to the imaging lens of the embodiment of the present application 9;
Figure 18 A to Figure 18 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 9, astigmatism curve and abnormal
Varied curve;
Figure 19 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 10;
Figure 20 A to Figure 20 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 10, astigmatism curve and abnormal
Varied curve;
Figure 21 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 11;
Figure 22 A to Figure 22 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 11, astigmatism curve and abnormal
Varied curve;
Figure 23 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 12;
Figure 24 A to Figure 24 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 12, astigmatism curve and abnormal
Varied curve;
Figure 25 shows the structural schematic diagram of the imaging lens according to the embodiment of the present application 13;
Figure 26 A to Figure 26 C respectively illustrates chromatic curve on the axis of the imaging lens of embodiment 13, astigmatism curve and abnormal
Varied curve.
Specific embodiment
Various aspects of the reference attached drawing to the application are made more detailed description by the application in order to better understand.It answers
Understand, the only description to the illustrative embodiments of the application is described in detail in these, rather than limits the application in any way
Range.In the specification, the identical element of identical reference numbers.Stating "and/or" includes associated institute
Any and all combinations of one or more of list of items.
It should be noted that in the present specification, first, second, third, etc. statement is only used for a feature and another spy
Sign distinguishes, without indicating any restrictions to feature.Therefore, without departing substantially from teachings of the present application, hereinafter
The first lens discussed are also known as the second lens or the third lens.
In the accompanying drawings, for ease of description, thickness, the size and shape of lens are slightly exaggerated.Specifically, attached drawing
Shown in spherical surface or aspherical shape be illustrated by way of example.That is, spherical surface or aspherical shape are not limited to attached drawing
Shown in spherical surface or aspherical shape.Attached drawing is merely illustrative and and non-critical drawn to scale.
Herein, near axis area refers to the region near optical axis.If lens surface is convex surface and does not define convex surface position
When setting, then it represents that the lens surface is convex surface near axis area is less than;If lens surface is concave surface and does not define the concave surface position
When, then it represents that the lens surface is concave surface near axis area is less than.Each lens are known as the object of the lens close to the surface of object side
Side, each lens are known as the image side surface of the lens close to the surface of image side.
It will also be appreciated that term " comprising ", " including ", " having ", "comprising" and/or " including ", when in this theory
It indicates there is stated feature, element and/or component when using in bright book, but does not preclude the presence or addition of one or more
Other feature, component, assembly unit and/or their combination.In addition, ought the statement of such as at least one of " ... " appear in institute
When after the list of column feature, entire listed feature is modified, rather than modifies the individual component in list.In addition, when describing this
When the embodiment of application, " one or more embodiments of the application " are indicated using "available".Also, term " illustrative "
It is intended to refer to example or illustration.
Unless otherwise defined, otherwise all terms (including technical terms and scientific words) used herein all have with
The application one skilled in the art's is generally understood identical meaning.It will also be appreciated that term (such as in everyday words
Term defined in allusion quotation) it should be interpreted as having and their consistent meanings of meaning in the context of the relevant technologies, and
It will not be explained with idealization or excessively formal sense, unless clear herein so limit.
It should be noted that in the absence of conflict, the features in the embodiments and the embodiments of the present application can phase
Mutually combination.The application is described in detail below with reference to the accompanying drawings and in conjunction with the embodiments.
The feature of the application, principle and other aspects are described in detail below.
Optical imaging lens according to the application illustrative embodiments may include such as six lens with focal power,
That is, the first lens, the second lens, the third lens, the 4th lens, the 5th lens and the 6th lens.This six-element lens is along optical axis
By object side to image side sequential.
In the exemplary embodiment, the first lens can have positive light coke;Second lens can have negative power, object
Side can be concave surface, and image side surface can be concave surface;The third lens can have positive light coke, and image side surface can be convex surface;4th lens
There can be negative power, object side can be concave surface;5th lens have positive light coke or negative power;6th lens have just
Focal power or negative power.By rationally controlling the first lens to the 4th power of lens and face type, it can effectively balance and be
The low order aberration of system makes system have good image quality.
In the exemplary embodiment, the object side of the first lens and image side surface can be convex surface.
In the exemplary embodiment, the object side of the third lens can be concave surface.
In the exemplary embodiment, the image side surface of the 4th lens can be concave surface.
In the exemplary embodiment, the object side of the 6th lens can be concave surface.
In the exemplary embodiment, the imaging lens of the application can meet conditional 2.0≤f/ImgH≤3.0, wherein
F is total effective focal length of imaging lens, and ImgH is the half of effective pixel area diagonal line length on the imaging surface of imaging lens.More
Specifically, f and ImgH can further meet 2.0≤f/ImgH≤2.5, for example, 2.27≤f/ImgH≤2.40.Meet conditional
2.0≤f/ImgH≤3.0 are conducive to that camera lens is made to have preferable image quality.
In the exemplary embodiment, the imaging lens of the application can meet 8 < f/T23 < 12 of conditional, wherein f is
Total effective focal length of imaging lens, T23 are the spacing distance of the second lens and the third lens on optical axis.More specifically, f and
T23 can further meet 9.5 < f/T23 < 10.5, for example, 9.87≤f/T23≤10.15.It can be with by control lens spacing
Effectively promote taking the photograph more than the enlargement ratio of increase shooting object improves image quality for imaging lens.
In the exemplary embodiment, the imaging lens of the application can meet 3 < f12/CT1 < 4.5 of conditional, wherein
F12 is the combined focal length of the first lens and the second lens, and CT1 is the first lens in the center thickness on optical axis.More specifically,
F12 and CT1 can further meet 3.5 < f12/CT1 < 4.5, for example, 3.72≤f12/CT1≤4.15.Rationally control first is thoroughly
The combined focal length of mirror and the second lens can effectively control deflection of light, the front end size of reduction system.
In the exemplary embodiment, the imaging lens of the application can meet conditional 0.5≤(T45+T56)/∑ AT <
0.9, wherein T45 is the spacing distance of the 4th lens and the 5th lens on optical axis, and T56 is that the 5th lens and the 6th lens exist
Spacing distance on optical axis, ∑ AT are the first lens spacing distance of two lens of arbitrary neighborhood on optical axis into the 6th lens
Summation.More specifically, T45, T56 and ∑ AT can further meet 0.5≤(T45+T56)/∑ AT < 0.7, for example, 0.57≤
(T45+T56)/∑AT≤0.63.4th lens account for the ratio at system integrated air interval to the airspace between the 6th lens
It is larger, the whole focal length of camera lens can be effectively increased, the ability for also making optical system that there is preferable balance dispersion.
In the exemplary embodiment, the imaging lens of the application can meet 0.6 f/f3≤1.0 < of conditional, wherein f
For total effective focal length of imaging lens, f3 is the effective focal length of the third lens.More specifically, f and f3 can further meet 0.73
≤f/f3≤0.99.The effective focal length for reasonably selecting the third lens, makes it have biggish positive light coke, is conducive to optical system
Ability with the preferable balance curvature of field.
In the exemplary embodiment, the imaging lens of the application can meet -1.5 < f/f4 < -1.0 of conditional, wherein
F is total effective focal length of imaging lens, and f4 is the effective focal length of the 4th lens.More specifically, f and f4 can further meet-
1.37≤f/f4≤-1.15.The negative power of 4th lens is controlled in zone of reasonableness, the whole focal length of camera lens can be increased, together
When can also have the function of balance the curvature of field.
In the exemplary embodiment, the imaging lens of the application can meet conditional 0.5≤| f/f5 |+| f/f6 | <
1.0, wherein f is total effective focal length of imaging lens, and f5 is the effective focal length of the 5th lens, and f6 is effective coke of the 6th lens
Away from.More specifically, f, f5 and f6 can further meet 0.53≤| f/f5 |+| f/f6 |≤0.84.The 5th lens of reasonable distribution and
The focal power of System Back-end is controlled in smaller range, can reduce the deflection angle of light, to reduce by the focal length of the 6th lens
The sensibility of system.
In the exemplary embodiment, the imaging lens of the application can meet -1.5 < -0.5 < R5/R8 of conditional,
In, R5 is the radius of curvature of the object side of the third lens, and R8 is the radius of curvature of the image side surface of the 4th lens.More specifically, R5
- 1.42≤R5/R8≤- 0.76 can further be met with R8.Rationally setting the third lens object side and the 4th lens image side surface
Radius of curvature makes optical system be easier to the balance curvature of field and distortion.
In the exemplary embodiment, the imaging lens of the application can meet 0 < R6/R7 < 1.0 of conditional, wherein R6
For the radius of curvature of the image side surface of the third lens, R7 is the radius of curvature of the object side of the 4th lens.More specifically, R6 and R7 into
One step can meet 0.3 < R6/R7 < 0.7, for example, 0.38≤R6/R7≤0.61.Rationally setting the third lens image side surface and the 4th
The radius of curvature of lens object side, can make optical system possess bigger aperture, improve the overall brightness of imaging.
In the exemplary embodiment, the imaging lens of the application can meet -1.0 < f/R2 < 0 of conditional, for example, f is
Total effective focal length of imaging lens, R2 are the radius of curvature of the image side surface of the first lens.More specifically, f and R2 can further expire
- 0.6 < -0.1 < f/R2 of foot, for example, -0.56≤f/R2≤- 0.21.The rationally radius of curvature of the first lens of setting can relatively be held
Easily balance aberration, modulation transfer function (MTF) performance of lifting system.
In the exemplary embodiment, the imaging lens of the application can meet conditional | f/R9 |+| f/R10 | < 1.2,
In, f is total effective focal length of imaging lens, and R9 is the radius of curvature of the object side of the 5th lens, and R10 is the image side of the 5th lens
The radius of curvature in face.More specifically, f, R9 and R10 can further meet 0 < | f/R9 |+| f/R10 | < 1.2, for example, 0.30≤
|f/R9|+|f/R10|≤1.13.The rationally radius of curvature of the 5th lens of setting, keeps its curved surface smoother, can effectively increase mirror
The whole focal length of head.Meanwhile the 5th power of lens of reasonable distribution, advantageously reduce the susceptibility of actual parts processing.
In the exemplary embodiment, the imaging lens of the application can meet conditional 0.5≤| f/R11 |+| f/R12 | <
1.5, wherein f is total effective focal length of imaging lens, and R11 is the radius of curvature of the object side of the 6th lens, and R12 is the 6th saturating
The radius of curvature of the image side surface of mirror.More specifically, f, R11 and R12 can further meet 0.50≤| f/R11 |+| f/R12 |≤
1.36.The rationally radius of curvature of the 6th lens of setting is conducive to adjust the incident ray of the 6th lens and the angle of emergent ray,
The chief ray angle (CRA) that optical system can be effectively controlled, is more advantageous to the matching of chip.
In the exemplary embodiment, the imaging lens of the application can meet conditional f/EPD < 2.5, wherein f be at
As total effective focal length of camera lens, EPD is the Entry pupil diameters of imaging lens.More specifically, f and EPD can further meet 2.18≤
f/EPD≤2.48.Meet conditional f/EPD < 2.5, system has the advantage of large aperture, can enhance system in the weaker ring of light
Imaging effect under border, while reducing the aberration of peripheral field.
In the exemplary embodiment, above-mentioned imaging lens may also include at least one diaphragm, to promote the imaging of camera lens
Quality.Diaphragm can be set as needed to be located at an arbitrary position, for example, diaphragm may be provided between object side and the first lens.
Optionally, above-mentioned optical imaging lens may also include optical filter for correcting color error ratio and/or for protecting
The protection glass of photosensitive element on imaging surface.
Present applicant proposes a kind of six chip telephoto lenses, which can be with collocation structure of wide-angle lens well known to other
It is in pairs to take the photograph camera lens, enlargement ratio ideal and the second best in quality picture are obtained in auto-focusing to realize.Meanwhile the application
Telephoto lens passes through on the axis between the center thickness and each lens of each power of lens of reasonable distribution, face type, each lens
Spacing etc. effectively reduces the volume of telephoto lens, reduces the susceptibility of telephoto lens and improve the processable of telephoto lens
Property, it produces and processes so that above-mentioned telephoto lens is more advantageous to and is applicable to portable electronic product.Meanwhile being matched by above-mentioned
The telephoto lens set can have small aberration, and can match high-resolution imager chip.
In presently filed embodiment, each lens mostly use aspherical mirror.The characteristics of non-spherical lens, is: from lens
To lens perimeter, curvature is consecutive variations at center.With the spherical lens from lens centre to lens perimeter with constant curvature
Difference, non-spherical lens have more preferably radius of curvature characteristic, have the advantages that improve and distort aberration and improvement astigmatic image error.It adopts
After non-spherical lens, the aberration occurred when imaging can be eliminated, as much as possible so as to improve image quality.
However, it will be understood by those of skill in the art that without departing from this application claims technical solution the case where
Under, the lens numbers for constituting imaging lens can be changed, to obtain each result and advantage described in this specification.Though for example,
It is so described by taking six lens as an example in embodiments, but the imaging lens are not limited to include six lens.If
It needs, which may also include the lens of other quantity.
The specific embodiment for being applicable to the imaging lens of above embodiment is further described with reference to the accompanying drawings.
Embodiment 1
Referring to Fig. 1 to Fig. 2 C description according to the imaging lens of the embodiment of the present application 1.Fig. 1 is shown according to the application
The structural schematic diagram of the imaging lens of embodiment 1.
As shown in Figure 1, sequentially being wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is convex surface, and image side surface S10 is concave surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is concave surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 1 shows surface type, radius of curvature, thickness, material and the circular cone of each lens of the imaging lens of embodiment 1
Coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 1
As shown in Table 1, the object side of any one lens of the first lens E1 into the 6th lens E6 and image side surface are
It is aspherical.In the present embodiment, the face type x of each non-spherical lens is available but is not limited to following aspherical formula and is defined:
Wherein, x be it is aspherical along optical axis direction when being highly the position of h, away from aspheric vertex of surface apart from rise;C is
Aspherical paraxial curvature, c=1/R (that is, inverse that paraxial curvature c is upper 1 mean curvature radius R of table);K be circular cone coefficient (
It has been provided in table 1);Ai is the correction factor of aspherical i-th-th rank.The following table 2 give can be used for it is each aspherical in embodiment 1
The high-order coefficient A of mirror surface S1-S124、A6、A8、A10、A12、A14、A16、A18And A20。
Table 2
Table 3 provides total effective focal length f, the first lens of the effective focal length f1 to f6 of each lens in embodiment 1, imaging lens
The maximum angle of half field-of view HFOV of distance TTL and imaging lens of the center of the object side S1 of E1 to imaging surface S15 on optical axis.
| f1(mm) | 2.56 | f6(mm) | -8.18 |
| f2(mm) | -3.92 | f(mm) | 6.02 |
| f3(mm) | 6.07 | TTL(mm) | 5.44 |
| f4(mm) | -4.40 | HFOV(°) | 23.3 |
| f5(mm) | -55.96 |
Table 3
Imaging lens in embodiment 1 meet:
F/ImgH=2.29, wherein f is total effective focal length of imaging lens, and ImgH is effective pixel region on imaging surface S15
The half of domain diagonal line length;
F/T23=10.15, wherein f is total effective focal length of imaging lens, and T23 is the second lens E2 and the third lens E3
Spacing distance on optical axis;
F12/CT1=4.12, wherein f12 is the combined focal length of the first lens E1 and the second lens E2, and CT1 is first saturating
Mirror E1 is in the center thickness on optical axis;
(T45+T56)/∑ AT=0.57, wherein T45 is interval distance of the 4th lens E4 and the 5th lens E5 on optical axis
From T56 is spacing distance of the 5th lens E5 and the 6th lens E6 on optical axis, and ∑ AT is the first lens E1 to the 6th lens E6
The summation of spacing distance of middle two lens of arbitrary neighborhood on optical axis;
F/f3=0.99, wherein f is total effective focal length of imaging lens, and f3 is the effective focal length of the third lens E3;
F/f4=-1.37, wherein f is total effective focal length of imaging lens, and f4 is the effective focal length of the 4th lens E4;
| f/f5 |+| f/f6 |=0.84, wherein f is total effective focal length of imaging lens, and f5 is the effective of the 5th lens E5
Focal length, f6 are the effective focal length of the 6th lens E6;
R5/R8=-1.29, wherein R5 is the radius of curvature of the object side S5 of the third lens E3, and R8 is the 4th lens E4's
The radius of curvature of image side surface S8;
R6/R7=0.49, wherein R6 is the radius of curvature of the image side surface S6 of the third lens E3, and R7 is the 4th lens E4's
The radius of curvature of object side S7;
F/R2=-0.55, wherein f is total effective focal length of imaging lens, and R2 is the song of the image side surface S2 of the first lens E1
Rate radius;
| f/R9 |+| f/R10 |=0.30, wherein f is total effective focal length of imaging lens, and R9 is the object of the 5th lens E5
The radius of curvature of side S9, R10 are the radius of curvature of the image side surface S10 of the 5th lens E5;
| f/R11 |+| f/R12 |=1.13, wherein f is total effective focal length of imaging lens, and R11 is the 6th lens E6's
The radius of curvature of object side S11, R12 are the radius of curvature of the image side surface S12 of the 6th lens E6;
F/EPD=2.28, wherein f is total effective focal length of imaging lens, and EPD is the Entry pupil diameters of imaging lens.
Fig. 2A shows chromatic curve on the axis of the imaging lens of embodiment 1, indicates the light of different wave length via mirror
Converging focal point after head deviates.Fig. 2 B shows the astigmatism curve of the imaging lens of embodiment 1, indicate meridianal image surface bending and
Sagittal image surface bending.Fig. 2 C shows the distortion curve of the imaging lens of embodiment 1, indicates the distortion in the case of different perspectives
Sizes values.A to Fig. 2 C is it is found that imaging lens given by embodiment 1 can be realized good image quality according to fig. 2.
Embodiment 2
Referring to Fig. 3 to Fig. 4 C description according to the imaging lens of the embodiment of the present application 2.In the present embodiment and following implementation
In example, for brevity, by clipped description similar to Example 1.Fig. 3 show according to the embodiment of the present application 2 at
As the structural schematic diagram of camera lens.
As shown in figure 3, sequentially being wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is convex surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is concave surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 4 shows surface type, radius of curvature, thickness, material and the circular cone of each lens of the imaging lens of embodiment 2
Coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 4
As shown in Table 4, in example 2, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 5 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 2, wherein each non-
Spherical surface type can be limited by the formula (1) provided in above-described embodiment 1.
Table 5
Table 6 provides total effective focal length f, the first lens of the effective focal length f1 to f6 of each lens in embodiment 2, imaging lens
The maximum angle of half field-of view HFOV of distance TTL and imaging lens of the center of the object side S1 of E1 to imaging surface S15 on optical axis.
| f1(mm) | 2.55 | f6(mm) | -12.60 |
| f2(mm) | -4.00 | f(mm) | 5.98 |
| f3(mm) | 7.23 | TTL(mm) | 5.44 |
| f4(mm) | -4.74 | HFOV(°) | 23.4 |
| f5(mm) | -35.37 |
Table 6
Fig. 4 A shows chromatic curve on the axis of the imaging lens of embodiment 2, indicates the light of different wave length via mirror
Converging focal point after head deviates.Fig. 4 B shows the astigmatism curve of the imaging lens of embodiment 2, indicate meridianal image surface bending and
Sagittal image surface bending.Fig. 4 C shows the distortion curve of the imaging lens of embodiment 2, indicates the distortion in the case of different perspectives
Sizes values.According to Fig. 4 A to Fig. 4 C it is found that imaging lens given by embodiment 2 can be realized good image quality.
Embodiment 3
The imaging lens according to the embodiment of the present application 3 are described referring to Fig. 5 to Fig. 6 C.Fig. 5 is shown according to this Shen
Please embodiment 3 imaging lens structural schematic diagram.
As shown in figure 5, sequentially being wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is convex surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is concave surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 7 shows surface type, radius of curvature, thickness, material and the circular cone of each lens of the imaging lens of embodiment 3
Coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 7
As shown in Table 7, in embodiment 3, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 8 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 3, wherein each non-
Spherical surface type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.3156E-02 | -3.0513E-02 | 1.1994E-01 | -2.4014E-01 | 2.9856E-01 | -2.3084E-01 | 1.0827E-01 | -2.7966E-02 | 2.9761E-03 |
| S2 | -1.8721E-02 | 1.9305E-01 | -5.2322E-01 | 1.0059E+00 | -1.3672E+00 | 1.2380E+00 | -7.0491E-01 | 2.2700E-01 | -3.1299E-02 |
| S3 | -1.0565E-01 | 4.0736E-01 | -9.0874E-01 | 1.4822E+00 | -1.7708E+00 | 1.4718E+00 | -7.9313E-01 | 2.4803E-01 | -3.3947E-02 |
| S4 | 2.3910E-02 | 1.2653E-01 | -6.4393E-01 | 2.0020E+00 | -4.1114E+00 | 5.2892E+00 | -4.0873E+00 | 1.7314E+00 | -3.0943E-01 |
| S5 | -1.0046E-01 | 1.3752E-01 | -7.3280E-01 | 3.3430E+00 | -1.3289E+01 | 3.0622E+01 | -4.0858E+01 | 2.9300E+01 | -8.7058E+00 |
| S6 | -5.4676E-01 | 2.7644E+00 | -9.8869E+00 | 2.6600E+01 | -5.2551E+01 | 7.1132E+01 | -6.2124E+01 | 3.1495E+01 | -7.0036E+00 |
| S7 | -3.9620E-01 | 1.4495E+00 | -3.7171E+00 | 6.9914E+00 | -8.7322E+00 | 6.7558E+00 | -3.4169E+00 | 1.3242E+00 | -3.2736E-01 |
| S8 | -2.5631E-01 | 6.2068E-01 | -1.4330E+00 | 3.1195E+00 | -4.7789E+00 | 5.0328E+00 | -3.5280E+00 | 1.4629E+00 | -2.6668E-01 |
| S9 | -5.9204E-03 | -9.8142E-03 | -1.5929E-02 | 3.7005E-02 | -4.9169E-03 | -1.8053E-02 | 1.2235E-02 | -3.1461E-03 | 2.9566E-04 |
| S10 | 6.5417E-03 | 1.7903E-02 | -7.5130E-02 | 1.0760E-01 | -8.5599E-02 | 4.1754E-02 | -1.2515E-02 | 2.1183E-03 | -1.5470E-04 |
| S11 | -8.7509E-02 | 8.5590E-02 | -6.3757E-02 | 3.3695E-02 | -1.0684E-02 | 1.4730E-03 | 8.2041E-05 | -4.5613E-05 | 3.5674E-06 |
| S12 | -1.2897E-01 | 1.0952E-01 | -9.2091E-02 | 5.7805E-02 | -2.5280E-02 | 7.4300E-03 | -1.4000E-03 | 1.5131E-04 | -6.9910E-06 |
Table 8
Table 9 provides total effective focal length f, the first lens of the effective focal length f1 to f6 of each lens in embodiment 3, imaging lens
The maximum angle of half field-of view HFOV of distance TTL and imaging lens of the center of the object side S1 of E1 to imaging surface S15 on optical axis.
| f1(mm) | 2.56 | f6(mm) | -13.51 |
| f2(mm) | -4.08 | f(mm) | 5.99 |
| f3(mm) | 6.31 | TTL(mm) | 5.44 |
| f4(mm) | -4.38 | HFOV(°) | 23.2 |
| f5(mm) | -21.45 |
Table 9
Fig. 6 A shows chromatic curve on the axis of the imaging lens of embodiment 3, indicates the light of different wave length via mirror
Converging focal point after head deviates.Fig. 6 B shows the astigmatism curve of the imaging lens of embodiment 3, indicate meridianal image surface bending and
Sagittal image surface bending.Fig. 6 C shows the distortion curve of the imaging lens of embodiment 3, indicates the distortion in the case of different perspectives
Sizes values.According to Fig. 6 A to Fig. 6 C it is found that imaging lens given by embodiment 3 can be realized good image quality.
Embodiment 4
The imaging lens according to the embodiment of the present application 4 are described referring to Fig. 7 to Fig. 8 C.Fig. 7 is shown according to this Shen
Please embodiment 4 imaging lens structural schematic diagram.
As shown in fig. 7, sequentially being wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is convex surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is concave surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 10 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 4
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 10
As shown in Table 10, in example 4, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 11 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 4, wherein each
Aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.2605E-02 | -2.8264E-02 | 1.0008E-01 | -1.8160E-01 | 2.0503E-01 | -1.4440E-01 | 6.1876E-02 | -1.4626E-02 | 1.4107E-03 |
| S2 | -1.8932E-02 | 1.7738E-01 | -4.3269E-01 | 7.4508E-01 | -9.2049E-01 | 7.6689E-01 | -4.0497E-01 | 1.2177E-01 | -1.5773E-02 |
| S3 | -1.0321E-01 | 3.6259E-01 | -6.9812E-01 | 9.3336E-01 | -8.8945E-01 | 5.8968E-01 | -2.5627E-01 | 6.6203E-02 | -7.7527E-03 |
| S4 | 1.6332E-02 | 1.4877E-01 | -7.2038E-01 | 2.2319E+00 | -4.5368E+00 | 5.7573E+00 | -4.3654E+00 | 1.8033E+00 | -3.1263E-01 |
| S5 | -1.0978E-01 | 2.7787E-01 | -2.0302E+00 | 9.7798E+00 | -3.2652E+01 | 6.7294E+01 | -8.3197E+01 | 5.6435E+01 | -1.6100E+01 |
| S6 | -5.2142E-01 | 2.6433E+00 | -9.3667E+00 | 2.4395E+01 | -4.5905E+01 | 5.9290E+01 | -5.0081E+01 | 2.4935E+01 | -5.5056E+00 |
| S7 | -4.0341E-01 | 1.5452E+00 | -4.0920E+00 | 7.6572E+00 | -8.8120E+00 | 5.5233E+00 | -1.9024E+00 | 6.6167E-01 | -2.4139E-01 |
| S8 | -2.6119E-01 | 6.4001E-01 | -1.4105E+00 | 2.7404E+00 | -3.5803E+00 | 3.1338E+00 | -1.8753E+00 | 7.0967E-01 | -1.2562E-01 |
| S9 | -3.7498E-03 | -4.9764E-02 | 1.4342E-01 | -2.7263E-01 | 3.3620E-01 | -2.4234E-01 | 9.9212E-02 | -2.1470E-02 | 1.9118E-03 |
| S10 | 1.1265E-02 | -1.4595E-02 | 2.9654E-02 | -5.1314E-02 | 5.0188E-02 | -2.7245E-02 | 8.1482E-03 | -1.2492E-03 | 7.5759E-05 |
| S11 | -8.4475E-02 | 5.4352E-02 | -8.6947E-03 | -1.3379E-02 | 1.2146E-02 | -5.1036E-03 | 1.2002E-03 | -1.4958E-04 | 7.6512E-06 |
| S12 | -1.2829E-01 | 9.2309E-02 | -7.1005E-02 | 4.5744E-02 | -2.1661E-02 | 6.9018E-03 | -1.3861E-03 | 1.5687E-04 | -7.4980E-06 |
Table 11
Table 12 provides the effective focal length f1 to f6 of each lens in embodiment 4, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.57 | f6(mm) | -11.43 |
| f2(mm) | -4.05 | f(mm) | 5.98 |
| f3(mm) | 7.04 | TTL(mm) | 5.44 |
| f4(mm) | -4.72 | HFOV(°) | 23.4 |
| f5(mm) | -25.23 |
Table 12
Fig. 8 A shows chromatic curve on the axis of the imaging lens of embodiment 4, indicates the light of different wave length via mirror
Converging focal point after head deviates.Fig. 8 B shows the astigmatism curve of the imaging lens of embodiment 4, indicate meridianal image surface bending and
Sagittal image surface bending.Fig. 8 C shows the distortion curve of the imaging lens of embodiment 4, indicates the distortion in the case of different perspectives
Sizes values.According to Fig. 8 A to Fig. 8 C it is found that imaging lens given by embodiment 4 can be realized good image quality.
Embodiment 5
The imaging lens according to the embodiment of the present application 5 are described referring to Fig. 9 to Figure 10 C.Fig. 9 is shown according to this Shen
Please embodiment 5 imaging lens structural schematic diagram.
As shown in figure 9, sequentially being wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is convex surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is concave surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 13 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 5
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 13
As shown in Table 13, in embodiment 5, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 14 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 5, wherein each
Aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.2064E-02 | -2.3066E-02 | 7.5528E-02 | -1.2074E-01 | 1.1723E-01 | -6.8011E-02 | 2.2406E-02 | -3.4885E-03 | 9.2461E-05 |
| S2 | -1.8586E-02 | 1.7122E-01 | -4.0224E-01 | 6.7915E-01 | -8.4238E-01 | 7.1215E-01 | -3.8216E-01 | 1.1655E-01 | -1.5278E-02 |
| S3 | -1.0213E-01 | 3.3903E-01 | -5.7088E-01 | 5.9634E-01 | -3.7577E-01 | 1.1601E-01 | 5.8059E-03 | -1.4069E-02 | 2.7139E-03 |
| S4 | 1.7436E-02 | 1.1608E-01 | -5.2045E-01 | 1.6002E+00 | -3.3622E+00 | 4.4298E+00 | -3.4659E+00 | 1.4664E+00 | -2.5880E-01 |
| S5 | -9.9404E-02 | 1.4704E-01 | -9.8730E-01 | 4.4286E+00 | -1.5440E+01 | 3.3019E+01 | -4.2243E+01 | 2.9580E+01 | -8.6886E+00 |
| S6 | -5.2320E-01 | 2.7086E+00 | -9.9999E+00 | 2.7096E+01 | -5.2412E+01 | 6.8873E+01 | -5.8648E+01 | 2.9191E+01 | -6.4039E+00 |
| S7 | -4.0376E-01 | 1.6583E+00 | -5.2381E+00 | 1.2769E+01 | -2.1662E+01 | 2.5110E+01 | -1.9885E+01 | 9.8057E+00 | -2.2167E+00 |
| S8 | -2.6585E-01 | 6.8727E-01 | -1.7255E+00 | 3.9107E+00 | -6.1224E+00 | 6.4944E+00 | -4.5461E+00 | 1.8837E+00 | -3.4487E-01 |
| S9 | -3.6387E-03 | -5.0244E-02 | 1.4338E-01 | -2.7238E-01 | 3.3637E-01 | -2.4255E-01 | 9.9292E-02 | -2.1492E-02 | 1.9156E-03 |
| S10 | 1.0297E-02 | -9.4899E-03 | 1.5875E-02 | -3.1458E-02 | 3.2716E-02 | -1.7649E-02 | 4.9627E-03 | -6.6777E-04 | 3.1063E-05 |
| S11 | -8.8299E-02 | 7.2275E-02 | -3.6305E-02 | 1.0838E-02 | -8.5299E-04 | -8.0173E-04 | 3.4491E-04 | -5.5916E-05 | 3.3106E-06 |
| S12 | -1.3377E-01 | 1.0832E-01 | -9.0773E-02 | 6.0064E-02 | -2.8263E-02 | 8.8736E-03 | -1.7581E-03 | 1.9701E-04 | -9.3570E-06 |
Table 14
Table 15 provides the effective focal length f1 to f6 of each lens in embodiment 5, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.58 | f6(mm) | -11.65 |
| f2(mm) | -4.02 | f(mm) | 5.99 |
| f3(mm) | 6.68 | TTL(mm) | 5.44 |
| f4(mm) | -4.58 | HFOV(°) | 22.4 |
| f5(mm) | -25.04 |
Table 15
Figure 10 A shows chromatic curve on the axis of the imaging lens of embodiment 5, indicates the light of different wave length via mirror
Converging focal point after head deviates.Figure 10 B shows the astigmatism curve of the imaging lens of embodiment 5, indicates meridianal image surface bending
It is bent with sagittal image surface.Figure 10 C shows the distortion curve of the imaging lens of embodiment 5, in the case of indicating different perspectives
Distort sizes values.According to Figure 10 A to Figure 10 C it is found that imaging lens given by embodiment 5 can be realized good imaging product
Matter.
Embodiment 6
The imaging lens according to the embodiment of the present application 6 are described referring to Figure 11 to Figure 12 C.Figure 11 is shown according to this
Apply for the structural schematic diagram of the imaging lens of embodiment 6.
As shown in figure 11, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is convex surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is concave surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 16 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 6
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 16
As shown in Table 16, in embodiment 6, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 17 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 6, wherein each
Aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.3055E-02 | -3.2943E-02 | 1.4496E-01 | -3.2166E-01 | 4.3682E-01 | -3.6465E-01 | 1.8254E-01 | -4.9986E-02 | 5.6786E-03 |
| S2 | -2.0428E-02 | 2.1821E-01 | -6.0070E-01 | 1.1218E+00 | -1.4405E+00 | 1.2060E+00 | -6.2481E-01 | 1.8220E-01 | -2.2895E-02 |
| S3 | -1.1219E-01 | 4.8105E-01 | -1.2171E+00 | 2.2205E+00 | -2.8851E+00 | 2.5380E+00 | -1.4139E+00 | 4.4868E-01 | -6.1624E-02 |
| S4 | 3.1267E-02 | 7.9267E-02 | -4.4627E-01 | 1.2374E+00 | -2.2387E+00 | 2.5498E+00 | -1.7323E+00 | 6.3509E-01 | -9.6775E-02 |
| S5 | -8.1451E-02 | -8.4300E-02 | 8.8626E-01 | -4.0887E+00 | 7.1463E+00 | -4.2391E+00 | -4.2379E+00 | 7.5290E+00 | -3.0982E+00 |
| S6 | -4.7474E-01 | 2.0060E+00 | -4.9675E+00 | 7.1960E+00 | -6.5286E+00 | 5.0044E+00 | -5.4772E+00 | 4.7663E+00 | -1.6401E+00 |
| S7 | -3.5408E-01 | 7.2764E-01 | 1.2630E+00 | -1.2855E+01 | 3.8809E+01 | -6.2134E+01 | 5.5947E+01 | -2.6816E+01 | 5.3462E+00 |
| S8 | -2.5215E-01 | 4.9666E-01 | -7.6719E-01 | 1.0381E+00 | -6.6055E-01 | 1.7848E-02 | 9.8127E-02 | 3.1389E-02 | -2.8465E-02 |
| S9 | -8.0912E-03 | -6.7920E-03 | -2.1736E-02 | 4.9312E-02 | -2.0538E-02 | -6.4199E-03 | 7.2230E-03 | -2.0015E-03 | 1.8924E-04 |
| S10 | 7.2025E-03 | 1.4388E-02 | -7.2278E-02 | 1.0353E-01 | -8.1075E-02 | 3.8710E-02 | -1.1304E-02 | 1.8531E-03 | -1.3019E-04 |
| S11 | -7.2409E-02 | 7.2369E-02 | -5.4504E-02 | 2.9050E-02 | -9.8617E-03 | 1.9088E-03 | -1.9194E-04 | 9.5762E-06 | -3.0055E-07 |
| S12 | -1.1944E-01 | 1.0355E-01 | -8.9580E-02 | 5.7400E-02 | -2.5398E-02 | 7.5112E-03 | -1.4180E-03 | 1.5295E-04 | -7.0451E-06 |
Table 17
Table 18 provides the effective focal length f1 to f6 of each lens in embodiment 6, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.64 | f6(mm) | -16.20 |
| f2(mm) | -4.42 | f(mm) | 5.99 |
| f3(mm) | 6.73 | TTL(mm) | 5.44 |
| f4(mm) | -4.65 | HFOV(°) | 23.4 |
| f5(mm) | -15.74 |
Table 18
Figure 12 A shows chromatic curve on the axis of the imaging lens of embodiment 6, indicates the light of different wave length via mirror
Converging focal point after head deviates.Figure 12 B shows the astigmatism curve of the imaging lens of embodiment 6, indicates meridianal image surface bending
It is bent with sagittal image surface.Figure 12 C shows the distortion curve of the imaging lens of embodiment 6, in the case of indicating different perspectives
Distort sizes values.According to figure 12 A to figure 12 C it is found that imaging lens given by embodiment 6 can be realized good imaging product
Matter.
Embodiment 7
The imaging lens according to the embodiment of the present application 7 are described referring to Figure 13 to Figure 14 C.Figure 13 is shown according to this
Apply for the structural schematic diagram of the imaging lens of embodiment 7.
As shown in figure 13, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is concave surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is concave surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 19 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 7
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 19
As shown in Table 19, in embodiment 7, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 20 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 7, wherein each
Aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.2588E-02 | -2.8891E-02 | 1.2547E-01 | -2.6917E-01 | 3.5358E-01 | -2.8515E-01 | 1.3774E-01 | -3.6309E-02 | 3.9392E-03 |
| S2 | -1.8988E-02 | 1.9259E-01 | -4.7146E-01 | 7.6497E-01 | -8.4575E-01 | 5.9915E-01 | -2.5759E-01 | 6.1899E-02 | -6.5153E-03 |
| S3 | -1.0499E-01 | 4.2638E-01 | -9.7235E-01 | 1.5445E+00 | -1.7196E+00 | 1.2908E+00 | -6.1594E-01 | 1.7106E-01 | -2.1410E-02 |
| S4 | 4.1534E-02 | 4.4455E-03 | -5.4133E-02 | -1.2430E-01 | 7.2954E-01 | -1.4572E+00 | 1.5030E+00 | -7.8901E-01 | 1.6506E-01 |
| S5 | -7.2504E-02 | -1.2370E-01 | 1.2820E+00 | -7.2468E+00 | 1.9616E+01 | -3.1829E+01 | 3.1195E+01 | -1.7187E+01 | 4.1458E+00 |
| S6 | -4.0133E-01 | 1.5357E+00 | -2.9873E+00 | 1.3949E-01 | 1.0817E+01 | -2.1373E+01 | 1.8408E+01 | -7.1176E+00 | 8.6947E-01 |
| S7 | -3.2459E-01 | 4.8365E-01 | 2.3487E+00 | -1.7265E+01 | 5.1045E+01 | -8.2161E+01 | 7.4818E+01 | -3.6386E+01 | 7.3789E+00 |
| S8 | -2.4849E-01 | 4.2053E-01 | -3.7297E-01 | -1.8390E-01 | 1.8599E+00 | -3.2729E+00 | 2.6708E+00 | -1.0665E+00 | 1.6838E-01 |
| S9 | -9.6849E-03 | -5.9005E-03 | -2.2896E-02 | 5.1600E-02 | -2.3536E-02 | -4.1042E-03 | 6.1883E-03 | -1.7573E-03 | 1.6584E-04 |
| S10 | 7.0968E-03 | 1.2535E-02 | -7.1273E-02 | 1.0218E-01 | -7.9456E-02 | 3.7582E-02 | -1.0847E-02 | 1.7525E-03 | -1.2093E-04 |
| S11 | -7.3752E-02 | 9.2067E-02 | -8.7796E-02 | 5.9610E-02 | -2.7529E-02 | 8.4124E-03 | -1.6563E-03 | 1.9136E-04 | -9.7503E-06 |
| S12 | -1.2544E-01 | 1.2408E-01 | -1.1195E-01 | 7.1521E-02 | -3.0882E-02 | 8.8104E-03 | -1.5935E-03 | 1.6411E-04 | -7.2129E-06 |
Table 20
Table 21 provides the effective focal length f1 to f6 of each lens in embodiment 7, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.68 | f6(mm) | -18.60 |
| f2(mm) | -4.58 | f(mm) | 5.99 |
| f3(mm) | 7.89 | TTL(mm) | 5.44 |
| f4(mm) | -5.21 | HFOV(°) | 22.4 |
| f5(mm) | -13.34 |
Table 21
Figure 14 A shows chromatic curve on the axis of the imaging lens of embodiment 7, indicates the light of different wave length via mirror
Converging focal point after head deviates.Figure 14 B shows the astigmatism curve of the imaging lens of embodiment 7, indicates meridianal image surface bending
It is bent with sagittal image surface.Figure 14 C shows the distortion curve of the imaging lens of embodiment 7, in the case of indicating different perspectives
Distort sizes values.According to Figure 14 A to Figure 14 C it is found that imaging lens given by embodiment 7 can be realized good imaging product
Matter.
Embodiment 8
The imaging lens according to the embodiment of the present application 8 are described referring to Figure 15 to Figure 16 C.Figure 15 is shown according to this
Apply for the structural schematic diagram of the imaging lens of embodiment 8.
As shown in figure 15, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have positive light coke, and object side S9 is concave surface, and image side surface S10 is convex surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is convex surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 22 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 8
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 22
As shown in Table 22, in embodiment 8, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 23 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 8, wherein each
Aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.2419E-02 | -2.5426E-02 | 8.6914E-02 | -1.5123E-01 | 1.6526E-01 | -1.1389E-01 | 4.8370E-02 | -1.1459E-02 | 1.1124E-03 |
| S2 | -2.0629E-02 | 2.0158E-01 | -5.4275E-01 | 1.0022E+00 | -1.2803E+00 | 1.0825E+00 | -5.7447E-01 | 1.7243E-01 | -2.2198E-02 |
| S3 | -1.0714E-01 | 3.9838E-01 | -8.4214E-01 | 1.2414E+00 | -1.2706E+00 | 8.7336E-01 | -3.8193E-01 | 9.6671E-02 | -1.0846E-02 |
| S4 | 1.0792E-02 | 1.4699E-01 | -5.4354E-01 | 1.3167E+00 | -2.2049E+00 | 2.4067E+00 | -1.6179E+00 | 6.0583E-01 | -9.7729E-02 |
| S5 | -1.0582E-01 | 2.5290E-01 | -1.9124E+00 | 8.9829E+00 | -2.8830E+01 | 5.6874E+01 | -6.7380E+01 | 4.3889E+01 | -1.2037E+01 |
| S6 | -5.1319E-01 | 2.7557E+00 | -1.0954E+01 | 3.2149E+01 | -6.6152E+01 | 9.0322E+01 | -7.8030E+01 | 3.8622E+01 | -8.3164E+00 |
| S7 | -4.1294E-01 | 1.7583E+00 | -6.1191E+00 | 1.6771E+01 | -3.1408E+01 | 3.8480E+01 | -3.0036E+01 | 1.3642E+01 | -2.7356E+00 |
| S8 | -2.5876E-01 | 5.8786E-01 | -1.2378E+00 | 2.5672E+00 | -3.7510E+00 | 3.7196E+00 | -2.4550E+00 | 9.6794E-01 | -1.6916E-01 |
| S9 | -1.0522E-02 | -2.7876E-03 | -4.0873E-03 | -1.8313E-02 | 7.2069E-02 | -7.3556E-02 | 3.4408E-02 | -7.7817E-03 | 6.9258E-04 |
| S10 | 1.3108E-02 | -1.1331E-02 | 2.2721E-02 | -4.3029E-02 | 4.4684E-02 | -2.5148E-02 | 7.7913E-03 | -1.2692E-03 | 8.7127E-05 |
| S11 | -8.1952E-02 | 4.7550E-02 | 7.6394E-03 | -2.2892E-02 | 1.2214E-02 | -3.2717E-03 | 4.8221E-04 | -3.6277E-05 | 1.0239E-06 |
| S12 | -1.3006E-01 | 1.0260E-01 | -9.0104E-02 | 6.7683E-02 | -3.5811E-02 | 1.2129E-02 | -2.5007E-03 | 2.8481E-04 | -1.3579E-05 |
Table 23
Table 24 provides the effective focal length f1 to f6 of each lens in embodiment 8, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.58 | f6(mm) | -8.62 |
| f2(mm) | -4.03 | f(mm) | 5.99 |
| f3(mm) | 7.13 | TTL(mm) | 5.44 |
| f4(mm) | -4.50 | HFOV(°) | 22.4 |
| f5(mm) | 2214.4 |
Table 24
Figure 16 A shows chromatic curve on the axis of the imaging lens of embodiment 8, indicates the light of different wave length via mirror
Converging focal point after head deviates.Figure 16 B shows the astigmatism curve of the imaging lens of embodiment 8, indicates meridianal image surface bending
It is bent with sagittal image surface.Figure 16 C shows the distortion curve of the imaging lens of embodiment 8, in the case of indicating different perspectives
Distort sizes values.According to Figure 16 A to Figure 16 C it is found that imaging lens given by embodiment 8 can be realized good imaging product
Matter.
Embodiment 9
The imaging lens according to the embodiment of the present application 9 are described referring to Figure 17 to Figure 18 C.Figure 17 shows according to this
Apply for the structural schematic diagram of the imaging lens of embodiment 9.
As shown in figure 17, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have positive light coke, and object side S9 is concave surface, and image side surface S10 is convex surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is convex surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 25 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 9
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 25
As shown in Table 25, in embodiment 9, the object side of any one lens of the first lens E1 into the 6th lens E6
It is aspherical with image side surface.Table 26 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 9, wherein each
Aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.1673E-02 | -1.9748E-02 | 6.5840E-02 | -1.0665E-01 | 1.0841E-01 | -6.9451E-02 | 2.7579E-02 | -6.1194E-03 | 5.3379E-04 |
| S2 | -2.0755E-02 | 2.0302E-01 | -5.4856E-01 | 1.0145E+00 | -1.2966E+00 | 1.0965E+00 | -5.8197E-01 | 1.7468E-01 | -2.2487E-02 |
| S3 | -1.0692E-01 | 3.9744E-01 | -8.4057E-01 | 1.2415E+00 | -1.2748E+00 | 8.8021E-01 | -3.8706E-01 | 9.8573E-02 | -1.1127E-02 |
| S4 | 8.7000E-03 | 1.6831E-01 | -6.5636E-01 | 1.6668E+00 | -2.8669E+00 | 3.1790E+00 | -2.1609E+00 | 8.1650E-01 | -1.3237E-01 |
| S5 | -1.0211E-01 | 2.0479E-01 | -1.6168E+00 | 7.8901E+00 | -2.6264E+01 | 5.3020E+01 | -6.3817E+01 | 4.2060E+01 | -1.1642E+01 |
| S6 | -5.1157E-01 | 2.7447E+00 | -1.0923E+01 | 3.2144E+01 | -6.6327E+01 | 9.0747E+01 | -7.8483E+01 | 3.8857E+01 | -8.3650E+00 |
| S7 | -4.1803E-01 | 1.8160E+00 | -6.4824E+00 | 1.8158E+01 | -3.4677E+01 | 4.3248E+01 | -3.4220E+01 | 1.5661E+01 | -3.1466E+00 |
| S8 | -2.5653E-01 | 5.7565E-01 | -1.2022E+00 | 2.4843E+00 | -3.5990E+00 | 3.5145E+00 | -2.2697E+00 | 8.7046E-01 | -1.4702E-01 |
| S9 | -1.1102E-02 | -1.4686E-03 | -5.7951E-03 | -1.7258E-02 | 7.2029E-02 | -7.4029E-02 | 3.4779E-02 | -7.9082E-03 | 7.0952E-04 |
| S10 | 1.4203E-02 | -1.2835E-02 | 2.5347E-02 | -4.6291E-02 | 4.7611E-02 | -2.6929E-02 | 8.4780E-03 | -1.4198E-03 | 1.0140E-04 |
| S11 | -8.3692E-02 | 4.9367E-02 | 7.2921E-03 | -2.3022E-02 | 1.2127E-02 | -3.1466E-03 | 4.3671E-04 | -2.9222E-05 | 6.1494E-07 |
| S12 | -1.3203E-01 | 1.0462E-01 | -9.2461E-02 | 7.0500E-02 | -3.7857E-02 | 1.2963E-02 | -2.6915E-03 | 3.0773E-04 | -1.4698E-05 |
Table 26
Table 27 provides the effective focal length f1 to f6 of each lens in embodiment 9, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.58 | f6(mm) | -7.95 |
| f2(mm) | -4.03 | f(mm) | 5.99 |
| f3(mm) | 7.20 | TTL(mm) | 5.44 |
| f4(mm) | -4.50 | HFOV(°) | 22.4 |
| f5(mm) | 103.5 |
Table 27
Figure 18 A shows chromatic curve on the axis of the imaging lens of embodiment 9, indicates the light of different wave length via mirror
Converging focal point after head deviates.Figure 18 B shows the astigmatism curve of the imaging lens of embodiment 9, indicates meridianal image surface bending
It is bent with sagittal image surface.Figure 18 C shows the distortion curve of the imaging lens of embodiment 9, in the case of indicating different perspectives
Distort sizes values.According to Figure 18 A to Figure 18 C it is found that imaging lens given by embodiment 9 can be realized good imaging product
Matter.
Embodiment 10
The imaging lens according to the embodiment of the present application 10 are described referring to Figure 19 to Figure 20 C.Figure 19 shows basis
The structural schematic diagram of the imaging lens of the embodiment of the present application 10.
As shown in figure 19, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is concave surface;6th lens E6 has positive light coke,
Its object side S11 is concave surface, and image side surface S12 is convex surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 28 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 10
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 28
As shown in Table 28, in embodiment 10, the object side of any one lens of the first lens E1 into the 6th lens E6
Face and image side surface are aspherical.Table 29 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 10, wherein
Each aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.0527E-02 | -1.6333E-02 | 5.4439E-02 | -8.1174E-02 | 6.6869E-02 | -2.4246E-02 | -2.1786E-03 | 4.4518E-03 | -1.0068E-03 |
| S2 | -1.2643E-02 | 1.3887E-01 | -3.3289E-01 | 5.8318E-01 | -7.2920E-01 | 6.0336E-01 | -3.1012E-01 | 8.8846E-02 | -1.0743E-02 |
| S3 | -1.0965E-01 | 3.7011E-01 | -7.2554E-01 | 1.0948E+00 | -1.2641E+00 | 1.0435E+00 | -5.6393E-01 | 1.7605E-01 | -2.3759E-02 |
| S4 | 2.5637E-02 | 5.3031E-02 | -2.7935E-01 | 1.0160E+00 | -2.4162E+00 | 3.4757E+00 | -2.9485E+00 | 1.3601E+00 | -2.6410E-01 |
| S5 | -7.2133E-02 | -3.1106E-01 | 3.1050E+00 | -1.6650E+01 | 5.0600E+01 | -9.5824E+01 | 1.1019E+02 | -7.0284E+01 | 1.9051E+01 |
| S6 | -4.9001E-01 | 2.4686E+00 | -7.7795E+00 | 1.6959E+01 | -2.5836E+01 | 2.6878E+01 | -1.8845E+01 | 8.2739E+00 | -1.7145E+00 |
| S7 | -4.0068E-01 | 1.4106E+00 | -3.0311E+00 | 2.4259E+00 | 6.6783E+00 | -2.1789E+01 | 2.6681E+01 | -1.5880E+01 | 3.8373E+00 |
| S8 | -2.7273E-01 | 6.5962E-01 | -1.5369E+00 | 3.3663E+00 | -5.1906E+00 | 5.5011E+00 | -3.8897E+00 | 1.6290E+00 | -2.9953E-01 |
| S9 | -6.0115E-03 | -2.8502E-02 | 7.0429E-02 | -1.3782E-01 | 1.9206E-01 | -1.4896E-01 | 6.2881E-02 | -1.3664E-02 | 1.2013E-03 |
| S10 | -2.9974E-03 | 1.0502E-02 | -3.6998E-02 | 4.1937E-02 | -2.9026E-02 | 1.4515E-02 | -5.0739E-03 | 1.0359E-03 | -8.8926E-05 |
| S11 | -4.5121E-02 | 3.5993E-02 | -8.0853E-03 | -6.9853E-03 | 5.9697E-03 | -2.0346E-03 | 3.6591E-04 | -3.4064E-05 | 1.2935E-06 |
| S12 | -7.6919E-02 | 4.3076E-02 | -2.5229E-02 | 1.3551E-02 | -6.0811E-03 | 1.8964E-03 | -3.7068E-04 | 4.0688E-05 | -1.8775E-06 |
Table 29
Table 30 provides the effective focal length f1 to f6 of each lens in embodiment 10, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.56 | f6(mm) | 2311.9 |
| f2(mm) | -4.03 | f(mm) | 5.99 |
| f3(mm) | 8.17 | TTL(mm) | 5.44 |
| f4(mm) | -4.80 | HFOV(°) | 22.4 |
| f5(mm) | -11.39 |
Table 30
Figure 20 A shows chromatic curve on the axis of the imaging lens of embodiment 10, indicate the light of different wave length via
Converging focal point after camera lens deviates.Figure 20 B shows the astigmatism curve of the imaging lens of embodiment 10, indicates that meridianal image surface is curved
The bending of bent and sagittal image surface.Figure 20 C shows the distortion curve of the imaging lens of embodiment 10, in the case of indicating different perspectives
Distortion sizes values.0A to Figure 20 C is it is found that imaging lens given by embodiment 10 can be realized good imaging according to fig. 2
Quality.
Embodiment 11
The imaging lens according to the embodiment of the present application 11 are described referring to Figure 21 to Figure 22 C.Figure 21 shows basis
The structural schematic diagram of the imaging lens of the embodiment of the present application 11.
As shown in figure 21, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is concave surface;6th lens E6 has positive light coke,
Its object side S11 is concave surface, and image side surface S12 is convex surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 31 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 11
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 31
As shown in Table 31, in embodiment 11, the object side of any one lens of the first lens E1 into the 6th lens E6
Face and image side surface are aspherical.Table 32 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 11, wherein
Each aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 1.0670E-02 | -1.8313E-02 | 6.1371E-02 | -9.4368E-02 | 8.1675E-02 | -3.3965E-02 | 1.3040E-03 | 3.9046E-03 | -9.9460E-04 |
| S2 | -1.3915E-02 | 1.4631E-01 | -3.4414E-01 | 5.8273E-01 | -7.0391E-01 | 5.6469E-01 | -2.8189E-01 | 7.8318E-02 | -9.1421E-03 |
| S3 | -1.1458E-01 | 4.0186E-01 | -8.2412E-01 | 1.2883E+00 | -1.5234E+00 | 1.2778E+00 | -6.9839E-01 | 2.1969E-01 | -2.9794E-02 |
| S4 | 2.1342E-02 | 8.6659E-02 | -4.2165E-01 | 1.4090E+00 | -3.1561E+00 | 4.3999E+00 | -3.6705E+00 | 1.6771E+00 | -3.2362E-01 |
| S5 | -6.4833E-02 | -3.2556E-01 | 3.1387E+00 | -1.6588E+01 | 4.9346E+01 | -9.1412E+01 | 1.0308E+02 | -6.4687E+01 | 1.7293E+01 |
| S6 | -4.9545E-01 | 2.4946E+00 | -7.3295E+00 | 1.3652E+01 | -1.6156E+01 | 1.1866E+01 | -5.7961E+00 | 2.2251E+00 | -5.4199E-01 |
| S7 | -4.1243E-01 | 1.3849E+00 | -2.2532E+00 | -1.8697E+00 | 1.8170E+01 | -3.8496E+01 | 4.0066E+01 | -2.1331E+01 | 4.6819E+00 |
| S8 | -2.7509E-01 | 6.2655E-01 | -1.2839E+00 | 2.4907E+00 | -3.4035E+00 | 3.2992E+00 | -2.2755E+00 | 9.7727E-01 | -1.8751E-01 |
| S9 | -8.2191E-03 | -2.7100E-02 | 6.5198E-02 | -1.2423E-01 | 1.7462E-01 | -1.3634E-01 | 5.7654E-02 | -1.2520E-02 | 1.0994E-03 |
| S10 | -3.9498E-03 | 7.8295E-03 | -3.5420E-02 | 3.9766E-02 | -2.5125E-02 | 1.0991E-02 | -3.4307E-03 | 6.5097E-04 | -5.3346E-05 |
| S11 | -4.0874E-02 | 3.7101E-02 | -1.4797E-02 | -1.5647E-03 | 3.7390E-03 | -1.5004E-03 | 2.9185E-04 | -2.8615E-05 | 1.1312E-06 |
| S12 | -7.7477E-02 | 4.8171E-02 | -3.2081E-02 | 1.8714E-02 | -8.7712E-03 | 2.8433E-03 | -5.7938E-04 | 6.6241E-05 | -3.1889E-06 |
Table 32
Table 33 provides the effective focal length f1 to f6 of each lens in embodiment 11, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.56 | f6(mm) | 246.1 |
| f2(mm) | -4.02 | f(mm) | 5.99 |
| f3(mm) | 8.01 | TTL(mm) | 5.44 |
| f4(mm) | -4.77 | HFOV(°) | 22.4 |
| f5(mm) | -10.69 |
Table 33
Figure 22 A shows chromatic curve on the axis of the imaging lens of embodiment 11, indicate the light of different wave length via
Converging focal point after camera lens deviates.Figure 22 B shows the astigmatism curve of the imaging lens of embodiment 11, indicates that meridianal image surface is curved
The bending of bent and sagittal image surface.Figure 22 C shows the distortion curve of the imaging lens of embodiment 11, in the case of indicating different perspectives
Distortion sizes values.2A to Figure 22 C is it is found that imaging lens given by embodiment 11 can be realized good imaging according to fig. 2
Quality.
Embodiment 12
The imaging lens according to the embodiment of the present application 12 are described referring to Figure 23 to Figure 24 C.Figure 23 shows basis
The structural schematic diagram of the imaging lens of the embodiment of the present application 12.
As shown in figure 23, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is concave surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is convex surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 34 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 12
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 34
As shown in Table 34, in embodiment 12, the object side of any one lens of the first lens E1 into the 6th lens E6
Face and image side surface are aspherical.Table 35 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 12, wherein
Each aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 9.0951E-03 | -4.8627E-03 | 1.7754E-02 | -1.5114E-02 | -2.5591E-03 | 1.7780E-02 | -1.5586E-02 | 6.0877E-03 | -9.6330E-04 |
| S2 | -7.0716E-03 | 1.0583E-01 | -2.3205E-01 | 4.0605E-01 | -5.5361E-01 | 5.1433E-01 | -2.9824E-01 | 9.6277E-02 | -1.3097E-02 |
| S3 | -9.6634E-02 | 2.7966E-01 | -3.8094E-01 | 2.7388E-01 | -2.6603E-02 | -1.2996E-01 | 1.1137E-01 | -3.8224E-02 | 4.8673E-03 |
| S4 | 3.4869E-02 | -4.9186E-02 | 2.7493E-01 | -7.4506E-01 | 1.0515E+00 | -8.0331E-01 | 2.6651E-01 | 1.6944E-02 | -2.5090E-02 |
| S5 | -8.0088E-02 | -2.6988E-01 | 2.8107E+00 | -1.5345E+01 | 4.7635E+01 | -9.1845E+01 | 1.0670E+02 | -6.8263E+01 | 1.8479E+01 |
| S6 | -4.9221E-01 | 2.4561E+00 | -8.5809E+00 | 2.2180E+01 | -4.0713E+01 | 5.0116E+01 | -3.9687E+01 | 1.8445E+01 | -3.8248E+00 |
| S7 | -3.8076E-01 | 1.2980E+00 | -3.0546E+00 | 4.3203E+00 | 1.2977E-01 | -1.1559E+01 | 1.8404E+01 | -1.2569E+01 | 3.3417E+00 |
| S8 | -2.8241E-01 | 7.9702E-01 | -2.3622E+00 | 6.2472E+00 | -1.1322E+01 | 1.3535E+01 | -1.0221E+01 | 4.3841E+00 | -8.0849E-01 |
| S9 | -5.1761E-03 | -2.6465E-02 | 6.3961E-02 | -1.3165E-01 | 1.8870E-01 | -1.4749E-01 | 6.2204E-02 | -1.3420E-02 | 1.1634E-03 |
| S10 | 2.9744E-04 | 1.1438E-02 | -3.8968E-02 | 5.3091E-02 | -4.7030E-02 | 2.8812E-02 | -1.1289E-02 | 2.4510E-03 | -2.2044E-04 |
| S11 | -4.3995E-02 | 1.6919E-02 | 1.6514E-02 | -2.1615E-02 | 1.0910E-02 | -3.0131E-03 | 4.7492E-04 | -4.0032E-05 | 1.4004E-06 |
| S12 | -7.3340E-02 | 3.7179E-02 | -2.6803E-02 | 1.9146E-02 | -9.9453E-03 | 3.2732E-03 | -6.5117E-04 | 7.1675E-05 | -3.3075E-06 |
Table 35
Table 36 provides the effective focal length f1 to f6 of each lens in embodiment 12, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
| f1(mm) | 2.57 | f6(mm) | -47.43 |
| f2(mm) | -4.06 | f(mm) | 5.99 |
| f3(mm) | 7.58 | TTL(mm) | 5.44 |
| f4(mm) | -4.60 | HFOV(°) | 22.4 |
| f5(mm) | -14.27 |
Table 36
Figure 24 A shows chromatic curve on the axis of the imaging lens of embodiment 12, indicate the light of different wave length via
Converging focal point after camera lens deviates.Figure 24 B shows the astigmatism curve of the imaging lens of embodiment 12, indicates that meridianal image surface is curved
The bending of bent and sagittal image surface.Figure 24 C shows the distortion curve of the imaging lens of embodiment 12, in the case of indicating different perspectives
Distortion sizes values.4A to Figure 24 C is it is found that imaging lens given by embodiment 12 can be realized good imaging according to fig. 2
Quality.
Embodiment 13
The imaging lens according to the embodiment of the present application 13 are described referring to Figure 25 to Figure 26 C.Figure 25 shows basis
The structural schematic diagram of the imaging lens of the embodiment of the present application 13.
As shown in figure 25, it is sequentially wrapped along optical axis by object side to image side according to the imaging lens of the application illustrative embodiments
Include: diaphragm STO, the first lens E1, the second lens E2, the third lens E3, the 4th lens E4, the 5th lens E5, the 6th lens E6,
Optical filter E7 and imaging surface S15.
First lens E1 has positive light coke, and object side S1 is convex surface, and image side surface S2 is convex surface;Second lens E2 has
Negative power, object side S3 are concave surface, and image side surface S4 is concave surface;The third lens E3 has positive light coke, and object side S5 is
Concave surface, image side surface S6 are convex surface;4th lens E4 has negative power, and object side S7 is concave surface, and image side surface S8 is concave surface;The
Five lens E5 have negative power, and object side S9 is concave surface, and image side surface S10 is concave surface;6th lens E6 has negative power,
Its object side S11 is concave surface, and image side surface S12 is convex surface.Optical filter E7 has object side S13 and image side surface S14.From object
Light sequentially passes through each surface S1 to S14 and is ultimately imaged on imaging surface S15.
Table 37 shows surface type, radius of curvature, thickness, material and the circle of each lens of the imaging lens of embodiment 13
Bore coefficient, wherein radius of curvature and the unit of thickness are millimeter (mm).
Table 37
As shown in Table 37, in embodiment 13, the object side of any one lens of the first lens E1 into the 6th lens E6
Face and image side surface are aspherical.Table 38 shows the high-order coefficient that can be used for each aspherical mirror in embodiment 13, wherein
Each aspherical face type can be limited by the formula (1) provided in above-described embodiment 1.
| Face number | A4 | A6 | A8 | A10 | A12 | A14 | A16 | A18 | A20 |
| S1 | 9.9287E-03 | -1.0432E-02 | 3.4218E-02 | -4.2234E-02 | 2.2188E-02 | 6.5032E-03 | -1.4369E-02 | 6.9181E-03 | -1.1891E-03 |
| S2 | -9.3698E-03 | 1.2521E-01 | -3.1245E-01 | 5.8300E-01 | -7.7601E-01 | 6.7797E-01 | -3.6599E-01 | 1.1005E-01 | -1.4006E-02 |
| S3 | -1.0075E-01 | 3.1474E-01 | -5.4727E-01 | 7.2126E-01 | -7.3934E-01 | 5.5999E-01 | -2.8668E-01 | 8.7218E-02 | -1.1705E-02 |
| S4 | 3.2687E-02 | -6.1276E-03 | -1.7383E-02 | 2.8256E-01 | -1.0763E+00 | 1.8940E+00 | -1.7908E+00 | 8.8322E-01 | -1.7968E-01 |
| S5 | -7.9243E-02 | -2.6414E-01 | 2.8376E+00 | -1.5853E+01 | 4.9993E+01 | -9.7733E+01 | 1.1515E+02 | -7.4765E+01 | 2.0532E+01 |
| S6 | -4.9353E-01 | 2.5116E+00 | -8.6382E+00 | 2.1565E+01 | -3.8077E+01 | 4.5258E+01 | -3.4810E+01 | 1.5815E+01 | -3.2240E+00 |
| S7 | -3.9627E-01 | 1.4764E+00 | -3.9645E+00 | 6.9696E+00 | -4.7557E+00 | -5.6819E+00 | 1.3971E+01 | -1.0719E+01 | 3.0289E+00 |
| S8 | -2.8207E-01 | 7.8352E-01 | -2.2224E+00 | 5.5853E+00 | -9.6290E+00 | 1.1024E+01 | -8.0553E+00 | 3.3745E+00 | -6.1147E-01 |
| S9 | -4.4976E-03 | -2.7501E-02 | 6.7876E-02 | -1.3775E-01 | 1.9499E-01 | -1.5190E-01 | 6.4175E-02 | -1.3925E-02 | 1.2196E-03 |
| S10 | -1.5928E-03 | 1.1158E-02 | -3.8284E-02 | 4.8897E-02 | -4.0118E-02 | 2.3163E-02 | -8.7563E-03 | 1.8575E-03 | -1.6382E-04 |
| S11 | -4.7248E-02 | 3.0610E-02 | 8.1571E-04 | -1.2172E-02 | 7.5898E-03 | -2.3291E-03 | 3.9614E-04 | -3.5568E-05 | 1.3151E-06 |
| S12 | -7.8521E-02 | 4.5765E-02 | -3.2076E-02 | 2.0736E-02 | -1.0044E-02 | 3.1854E-03 | -6.1998E-04 | 6.7060E-05 | -3.0394E-06 |
Table 38
Table 39 provides the effective focal length f1 to f6 of each lens in embodiment 13, total effective focal length f of imaging lens, first thoroughly
The maximum angle of half field-of view of distance TTL and imaging lens of the center of the object side S1 of mirror E1 to imaging surface S15 on optical axis
HFOV。
Table 39
Figure 26 A shows chromatic curve on the axis of the imaging lens of embodiment 13, indicate the light of different wave length via
Converging focal point after camera lens deviates.Figure 26 B shows the astigmatism curve of the imaging lens of embodiment 13, indicates that meridianal image surface is curved
The bending of bent and sagittal image surface.Figure 26 C shows the distortion curve of the imaging lens of embodiment 13, in the case of indicating different perspectives
Distortion sizes values.6A to Figure 26 C is it is found that imaging lens given by embodiment 13 can be realized good imaging according to fig. 2
Quality.
To sum up, embodiment 1 to embodiment 13 meets relationship shown in table 40 respectively.
| Conditional embodiment | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 |
| f/ImgH | 2.29 | 2.27 | 2.28 | 2.27 | 2.28 | 2.28 | 2.28 | 2.40 | 2.40 | 2.40 | 2.40 | 2.40 | 2.40 |
| f/T23 | 10.15 | 10.02 | 10.03 | 9.99 | 10.01 | 10.01 | 10.01 | 10.03 | 10.04 | 9.90 | 9.87 | 9.96 | 9.93 |
| f12/CT1 | 4.12 | 4.10 | 4.14 | 3.90 | 3.90 | 4.14 | 4.15 | 3.90 | 3.91 | 3.73 | 3.72 | 3.79 | 3.76 |
| (T45+T56)/∑AT | 0.57 | 0.60 | 0.61 | 0.61 | 0.61 | 0.63 | 0.63 | 0.61 | 0.61 | 0.58 | 0.58 | 0.58 | 0.58 |
| f/f3 | 0.99 | 0.83 | 0.95 | 0.85 | 0.90 | 0.89 | 0.76 | 0.84 | 0.83 | 0.73 | 0.75 | 0.79 | 0.76 |
| f/f4 | -1.37 | -1.26 | -1.37 | -1.27 | -1.31 | -1.29 | -1.15 | -1.33 | -1.33 | -1.25 | -1.26 | -1.30 | -1.27 |
| |f/f5|+|f/f6| | 0.84 | 0.64 | 0.72 | 0.76 | 0.75 | 0.75 | 0.77 | 0.70 | 0.81 | 0.53 | 0.58 | 0.55 | 0.54 |
| R5/R8 | -1.29 | -1.01 | -0.96 | -0.93 | -1.02 | -0.79 | -0.76 | -1.16 | -1.17 | -1.38 | -1.42 | -1.38 | -1.37 |
| R6/R7 | 0.49 | 0.55 | 0.59 | 0.57 | 0.56 | 0.61 | 0.56 | 0.54 | 0.54 | 0.40 | 0.38 | 0.44 | 0.42 |
| f/R2 | -0.55 | -0.53 | -0.48 | -0.55 | -0.54 | -0.29 | -0.21 | -0.55 | -0.56 | -0.47 | -0.47 | -0.48 | -0.47 |
| |f/R9|+|f/R10| | 0.30 | 1.03 | 0.97 | 1.13 | 1.04 | 0.84 | 0.82 | 1.00 | 1.10 | 0.96 | 1.02 | 0.77 | 0.91 |
| |f/R11|+|f/R12| | 1.13 | 0.73 | 0.68 | 0.81 | 0.79 | 0.57 | 0.50 | 1.19 | 1.36 | 0.60 | 0.63 | 0.60 | 0.54 |
| f/EPD | 2.28 | 2.28 | 2.28 | 2.18 | 2.19 | 2.48 | 2.48 | 2.18 | 2.18 | 2.19 | 2.19 | 2.19 | 2.19 |
Table 40
The application also provides a kind of imaging device, and electronics photosensitive element can be photosensitive coupling element (CCD) or complementation
Property matal-oxide semiconductor element (CMOS).Imaging device can be the independent imaging equipment of such as digital camera, be also possible to
The image-forming module being integrated on the mobile electronic devices such as mobile phone.The imaging device is equipped with imaging lens described above.
Above description is only the preferred embodiment of the application and the explanation to institute's application technology principle.Those skilled in the art
Member is it should be appreciated that invention scope involved in the application, however it is not limited to technology made of the specific combination of above-mentioned technical characteristic
Scheme, while should also cover in the case where not departing from the inventive concept, it is carried out by above-mentioned technical characteristic or its equivalent feature
Any combination and the other technical solutions formed.Such as features described above has similar function with (but being not limited to) disclosed herein
Can technical characteristic replaced mutually and the technical solution that is formed.
Claims (26)
1. imaging lens, along optical axis by object side to image side sequentially include: the first lens, the second lens, the third lens, the 4th thoroughly
Mirror, the 5th lens and the 6th lens, which is characterized in that
First lens have positive light coke;
Second lens have negative power, and object side and image side surface are concave surface;
The third lens have positive light coke, and image side surface is convex surface;
4th lens have negative power, and object side is concave surface;
5th lens and the 6th lens all have positive light coke or negative power;
Total effective focal length f of the imaging lens and the effective pixel area diagonal line length on the imaging surface of the imaging lens
Half ImgH meets 2.0≤f/ImgH≤3.0.
2. imaging lens according to claim 1, which is characterized in that total effective focal length f of the imaging lens with it is described
The spacing distance T23 of second lens and the third lens on the optical axis meets 8 < f/T23 < 12.
3. imaging lens according to claim 1, which is characterized in that the combination of first lens and second lens
Focal length f12 and first lens are in the 3 < f12/CT1 < 4.5 of center thickness CT1 satisfaction on the optical axis.
4. imaging lens according to claim 1, which is characterized in that the 4th lens and the 5th lens are described
Spacing distance T45, the spacing distance T56 of the 5th lens and the 6th lens on the optical axis on optical axis with it is described
The summation ∑ AT of the first lens spacing distance of two lens of arbitrary neighborhood on the optical axis into the 6th lens meets 0.5
≤ (T45+T56)/∑ AT < 0.9.
5. imaging lens according to claim 1, which is characterized in that the radius of curvature R 5 of the object side of the third lens
Meet -1.5 < R5/R8 < -0.5 with the radius of curvature R 8 of the image side surface of the 4th lens.
6. imaging lens according to claim 1, which is characterized in that the radius of curvature R 6 of the image side surface of the third lens
Meet 0 < R6/R7 < 1.0 with the radius of curvature R 7 of the object side of the 4th lens.
7. imaging lens according to claim 5 or 6, which is characterized in that total effective focal length f of the imaging lens and institute
The effective focal length f3 for stating the third lens meets 0.6 f/f3≤1.0 <.
8. imaging lens according to claim 5 or 6, which is characterized in that total effective focal length f of the imaging lens and institute
The effective focal length f4 for stating the 4th lens meets -1.5 < f/f4 < -1.0.
9. imaging lens according to claim 1, which is characterized in that total effective focal length f of the imaging lens, described
The radius of curvature R 10 of the image side surface of the radius of curvature R 9 of the object side of five lens and the 5th lens meets | f/R9 |+| f/
R10 | < 1.2.
10. imaging lens according to claim 1, which is characterized in that total effective focal length f of the imaging lens, described
The satisfaction of radius of curvature R 12 0.5 of the image side surface of the radius of curvature R 11 of the object side of 6th lens and the 6th lens≤| f/
R11 |+| f/R12 | < 1.5.
11. imaging lens according to claim 9 or 10, which is characterized in that total effective focal length f of the imaging lens,
The effective focal length f6 of the effective focal length f5 of 5th lens and the 6th lens meets 0.5≤| f/f5 |+| f/f6 | <
1.0。
12. imaging lens according to claim 1, which is characterized in that total effective focal length f of the imaging lens with it is described
The radius of curvature R 2 of the image side surface of first lens meets -1.0 < f/R2 < 0.
13. imaging lens according to claim 1, which is characterized in that total effective focal length f of the imaging lens with it is described
The Entry pupil diameters EPD of imaging lens meets f/EPD < 2.5.
14. imaging lens, along optical axis by object side to image side sequentially include: the first lens, the second lens, the third lens, the 4th thoroughly
Mirror, the 5th lens and the 6th lens, which is characterized in that
First lens have positive light coke;
Second lens have negative power, and object side and image side surface are concave surface;
The third lens have positive light coke, and image side surface is convex surface;
4th lens have negative power, and object side is concave surface;
5th lens and the 6th lens all have positive light coke or negative power;
Effective coke of total effective focal length f of the imaging lens, the effective focal length f5 of the 5th lens and the 6th lens
Away from f6 satisfaction 0.5≤| f/f5 |+| f/f6 | < 1.0.
15. imaging lens according to claim 14, which is characterized in that the group of first lens and second lens
Complex focus f12 and first lens are in the 3 < f12/CT1 < 4.5 of center thickness CT1 satisfaction on the optical axis.
16. imaging lens according to claim 14, which is characterized in that total effective focal length f of the imaging lens and institute
The effective focal length f3 for stating the third lens meets 0.6 f/f3≤1.0 <.
17. imaging lens according to claim 14, which is characterized in that total effective focal length f of the imaging lens and institute
The effective focal length f4 for stating the 4th lens meets -1.5 < f/f4 < -1.0.
18. imaging lens according to claim 14, which is characterized in that the 4th lens and the 5th lens are in institute
State the spacing distance T56 and institute of spacing distance T45, the 5th lens and the 6th lens on the optical axis on optical axis
The summation ∑ AT for stating the first lens spacing distance of two lens of arbitrary neighborhood on the optical axis into the 6th lens meets
0.5≤(T45+T56)/∑ AT < 0.9.
19. imaging lens according to claim 18, which is characterized in that total effective focal length f of the imaging lens and institute
It states the spacing distance T23 of the second lens and the third lens on the optical axis and meets 8 < f/T23 < 12.
20. imaging lens according to claim 18, which is characterized in that total effective focal length f of the imaging lens and institute
The radius of curvature R 2 for stating the image side surface of the first lens meets -1.0 < f/R2 < 0.
21. imaging lens according to claim 18, which is characterized in that the radius of curvature of the object side of the third lens
The radius of curvature R 8 of the image side surface of R5 and the 4th lens meets -1.5 < R5/R8 < -0.5.
22. imaging lens according to claim 18, which is characterized in that the radius of curvature of the image side surface of the third lens
The radius of curvature R 7 of the object side of R6 and the 4th lens meets 0 < R6/R7 < 1.0.
23. imaging lens according to claim 18, which is characterized in that total effective focal length f of the imaging lens, described
The radius of curvature R 10 of the image side surface of the radius of curvature R 9 of the object side of 5th lens and the 5th lens meets | f/R9 |+| f/
R10 | < 1.2.
24. imaging lens according to claim 18, which is characterized in that total effective focal length f of the imaging lens, described
The satisfaction of radius of curvature R 12 0.5 of the image side surface of the radius of curvature R 11 of the object side of 6th lens and the 6th lens≤| f/
R11 |+| f/R12 | < 1.5.
25. imaging lens described in any one of 4 to 24 according to claim 1, which is characterized in that the imaging lens always have
The Entry pupil diameters EPD of effect focal length f and the imaging lens meets f/EPD < 2.5.
26. imaging lens according to claim 25, which is characterized in that total effective focal length f of the imaging lens and institute
The half ImgH for stating the effective pixel area diagonal line length on the imaging surface of imaging lens meets 2.0≤f/ImgH≤3.0.
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108469668A (en) * | 2018-06-01 | 2018-08-31 | 浙江舜宇光学有限公司 | Imaging lens |
| TWI681229B (en) * | 2019-03-06 | 2020-01-01 | 大立光電股份有限公司 | Imaging optical lens assembly, image capturing unit and electronic device |
| TWI722839B (en) * | 2020-03-06 | 2021-03-21 | 大陸商玉晶光電(廈門)有限公司 | Optical imaging lens |
-
2018
- 2018-06-01 CN CN201820842143.0U patent/CN208477187U/en active Active
Cited By (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108469668A (en) * | 2018-06-01 | 2018-08-31 | 浙江舜宇光学有限公司 | Imaging lens |
| CN109725408A (en) * | 2018-06-01 | 2019-05-07 | 浙江舜宇光学有限公司 | Imaging lens |
| CN109725408B (en) * | 2018-06-01 | 2021-03-30 | 浙江舜宇光学有限公司 | Imaging lens |
| US11698514B2 (en) | 2018-06-01 | 2023-07-11 | Zhejiang Sunny Optical Co., Ltd | Imaging lens assembly |
| TWI681229B (en) * | 2019-03-06 | 2020-01-01 | 大立光電股份有限公司 | Imaging optical lens assembly, image capturing unit and electronic device |
| CN111665613A (en) * | 2019-03-06 | 2020-09-15 | 大立光电股份有限公司 | Image capturing optical lens assembly, image capturing device and electronic device |
| CN111665613B (en) * | 2019-03-06 | 2022-04-26 | 大立光电股份有限公司 | Image capturing optical lens assembly, image capturing device and electronic device |
| TWI722839B (en) * | 2020-03-06 | 2021-03-21 | 大陸商玉晶光電(廈門)有限公司 | Optical imaging lens |
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