CN202093231U - Near-infrared camera lenses - Google Patents
Near-infrared camera lenses Download PDFInfo
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- CN202093231U CN202093231U CN2011202182398U CN201120218239U CN202093231U CN 202093231 U CN202093231 U CN 202093231U CN 2011202182398 U CN2011202182398 U CN 2011202182398U CN 201120218239 U CN201120218239 U CN 201120218239U CN 202093231 U CN202093231 U CN 202093231U
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Abstract
The utility model discloses near-infrared camera lenses, which sequentially comprise four groups of lenses along optical axis from object space to image space. A first lens is a falcate lens of negative power, a convex surface faces the object space, and aspheric surface is adopted. A second lens is a falcate lens of positive or negative power, and the convex surface faces the image space. A third lens is a biconvex, convexo-plane or falcate lens of positive power, and the convex surface faces the object space when the third lens is convexo-plane or falcate. A fourth lens is a lens of positive power, and aspheric surface is adopted. Due to the design, the near-infrared camera lenses can ensure imaging quality at the angle of large aperture and large field of view and meanwhile has the technical effect of small distortion.
Description
Technical field
The utility model relates to a kind of near infrared camera lens, relates to the near infrared camera lens of a kind of large aperture of being made up of four set of contact lenses, wide-angle, little distortion specifically.
Background technology
The optical lens that existing digital product is used generally all is to adopt common optical lens, and the visual angle is little, and image quality is not high.Adopt wide-angle lens can overcome this shortcoming, but the greatest problem that common wide-angle lens exists is being imaged on behind the optical effect of camera lens of object, have the phenomenon that image is distorted, because spherical glass is only arranged in the past, (or be called the barreled distortion for the distortion receipts of revisal imaging are poor, promptly be in the imaging more near the edge, image has expansion more and straight-line bending becomes the phenomenon of camber line), need installing crescent negative eyeglass of multi-disc or crescent positive eyeglass additional, could to eliminate this receipts at the front end of camera lens poor.When common wide-angle lens is spent at camera lens visual angle 80, need 8 to 10 eyeglasses, more than 100 degree of camera lens visual angle, need more than 10 to 12, cause the oversize and weight increase of camera lens.As seen common wide-angle lens, especially near infrared wide-angle lens, complex structure also exists the general all smaller phenomenon of relative aperture in addition.
Along with the progress of optics plastic material and the manufacturing technology universalness of aspherical lens, just there are many small-sized and light-weighted camera lenses to occur.Especially use after the aspherical lens, when camera lens visual angle 80 is spent, only need 3 to 4 eyeglasses, when camera lens visual angle 100 is spent, only need 4 to 5 eyeglasses, when camera lens visual angle 120 degree are above, only need 5 to 6 eyeglasses, the visible optical camera lens is to small-sized and lightweight development.
If the eyeglass number of camera lens very little, probably can't provide preferable image quality.In order to guarantee image quality, a lot of patents all provide 4 camera lenses that eyeglass is formed, such as in patent No. CN200610138436.2, CN200710111925.3, CN200710201438.6, CN200810305113.7, CN200910302836.6 etc.It is the structure of the eyeglass of positive light coke that these camera lenses have all adopted first eyeglass, and other eyeglasses are had nothing in common with each other in design.
But can find that these camera lenses effect aspect wide-angle is also relatively poor relatively, and the problem of image fault also can't overcome.And these patents are not considered the influence of temperature variation to camera lens.Because the contemporary optics instrument requires to have stable performance usually in the ambient temperature range of a broad, need disappearing to system, heat is poor to be designed.The heat difference design that disappears of optical system is by certain compensation technique, makes optical system keep image quality constant in a wider temperature range, three kinds of methods is arranged usually: active, mechanical passive type of machinery and PASSIVE OPTICAL formula.As modal camera lens in the optical instrument, heat is poor in order to realize disappearing, and generally also is to start with from above three kinds of methods, but these methods make lens construction complexity more, cause that cost raises, the camera lens volume becomes problem such as big, is incongruent to the requirement of portable camera lens.
The utility model content
In view of the above problems, technical purpose of the present utility model is to overcome the shortcoming of near infrared camera lens in the prior art, and a kind of simple lens structure that has is provided, and can realize the near infrared camera lens of large aperture, wide-angle, little distortion.
In order to realize above-mentioned technical purpose, the utility model is realized by following technical scheme:
A kind of near infrared camera lens, this camera lens comprises four set of contact lenses from the object side to the image side successively along optical axis, and first eyeglass is the falcate eyeglass of negative power, and convex surface adopts aspheric surface towards object space; Second eyeglass is the falcate eyeglass of plus or minus focal power, and convex surface is towards picture side; Prismatic glasses is lenticular, the convexo-plane or the falcate eyeglass of positive light coke, and when plano-convex or falcate, convex surface is towards object space; The 4th eyeglass is the eyeglass of positive light coke, adopts aspheric surface.
Preferably, described near infrared camera lens satisfies following relational expression:
①-0.5<f/f1<-0.2
Wherein f1 is the focal length of first eyeglass, and f is the focal length of total system;
②|f2|>|f1|
Wherein | f1| is the absolute value of the focal length of first eyeglass, | f2| is the absolute value of the focal length of second eyeglass;
③f4>f3
Wherein f3 is the focal length of prismatic glasses, and f4 is the focal length of the 4th eyeglass;
④0.2<f/f3<0.6
Wherein f3 is the focal length of prismatic glasses, and f is the focal length of total system.
By determining above-mentioned focal length relation, can obviously improve the optical property of camera lens, such as large aperture, wide-angle, little distortion etc.
Preferably, described near infrared camera lens also comprises diaphragm, and described diaphragm is between described second eyeglass and prismatic glasses.
Further, described near infrared camera lens satisfies following relational expression:
0<dn3/dt<1E-05,-1E-3<dn1/dt<-5E-5,-1E-3<dn2/dt<-5E-5
Wherein dn1/dt is the relative temperature variation of refractive index of first eyeglass;
Wherein dn2/dt is the relative temperature variation of refractive index of second eyeglass;
Wherein dn3/dt is the relative temperature variation of refractive index of the 3rd eyeglass.
Preferably, described prismatic glasses is a glass mirror, and described first and second and four eyeglasses are glass lens.
Preferably, described near infrared camera lens also comprises optical filter, and described optical filter is arranged between second eyeglass and the prismatic glasses.
In addition, the stationkeeping of each eyeglass.
The utility model adopts the eyeglass combination of different profiles and utilizes focal power to distribute the function that has realized large aperture, wide-angle, little distortion, can reach FNO<1, field angle>90 degree, distortion<5%.And then, be limited in particular range by focal length relation to each eyeglass, can make optical property excellent more.Further, by the relation of restriction dn/dt, heat difference effect effectively can realize disappearing.
Description of drawings
By the description of its exemplary embodiment being carried out below in conjunction with accompanying drawing, the above-mentioned feature and advantage of the utility model will become apparent and understand easily.
Fig. 1 is the embodiment 1 concrete structure synoptic diagram of the related near infrared camera lens of the utility model;
Fig. 2 is that the axle during 25 ℃ near infrared camera lens is gone up chromaticity difference diagram among the utility model embodiment 1;
Fig. 3 is the astigmatism figure during 25 ℃ near infrared camera lens among the utility model embodiment 1;
Fig. 4 is the distortion figure during 25 ℃ near infrared camera lens among the utility model embodiment 1;
Fig. 5 is the ratio chromatism, figure during 25 ℃ near infrared camera lens among the utility model embodiment 1;
Fig. 6 is the FFT MTF figure during 25 ℃ near infrared camera lens among the utility model embodiment 1;
Fig. 7 is the FFT MTF figure during 5 ℃ near infrared camera lens among the utility model embodiment 1;
Fig. 8 is the FFT MTF figure during 50 ℃ near infrared camera lens among the utility model embodiment 1;
Fig. 9 is that the axle during 25 ℃ near infrared camera lens is gone up chromaticity difference diagram among the utility model embodiment 2;
Figure 10 is the astigmatism figure during 25 ℃ near infrared camera lens among the utility model embodiment 2;
Figure 11 is the distortion figure during 25 ℃ near infrared camera lens among the utility model embodiment 2;
Figure 12 is the ratio chromatism, figure during 25 ℃ near infrared camera lens among the utility model embodiment 2;
Figure 13 is the FFT MTF figure during 25 ℃ near infrared camera lens among the utility model embodiment 2;
Figure 14 is the FFT MTF figure during 5 ℃ near infrared camera lens among the utility model embodiment 2;
Figure 15 is the FFT MTF figure during 50 ℃ near infrared camera lens among the utility model embodiment 2;
Embodiment
Below in conjunction with accompanying drawing the utility model is described in further detail.
Fig. 1 is the concrete structure synoptic diagram of the embodiment 1 of the related near infrared camera lens of the utility model.
As shown in the figure, near infrared camera lens of the present utility model mainly is made up of four set of contact lenses, comprises four set of contact lenses from the object side to the image side successively along optical axis, and the first eyeglass E1 is the falcate eyeglass of negative power, and convex surface adopts aspheric surface towards object space; The second eyeglass E2 is the falcate eyeglass of positive light coke, and convex surface is towards picture side; Prismatic glasses E3 is the convexo-plane eyeglass of positive light coke, and convex surface is towards object space; The 4th eyeglass E4 is the eyeglass of positive light coke, adopts aspheric surface.
In addition, between the second eyeglass E2 and prismatic glasses E3, also be provided with optical filter E5 and diaphragm E6.Rely on the design of optical filter E5 and diaphragm E6, can reduce the incident angle of the chief ray of Integrated lens, thereby eliminated the various brightness problem that cause because of the wavelength shift of light with comparalive ease, improve the optical quality of whole imaging.And the position of described above each eyeglass is fixed, and each eyeglass is not removable.
Further, described prismatic glasses E3 is a glass mirror, and the described first eyeglass E1, the second eyeglass E2 and the 4th eyeglass E4 are glass lens.By adopting glass to mould the structure of mixing, can overcome the heat that disappears poor.And described eyeglass need satisfy following expression formula:
dn1/dt=dn2/dt=-1.022E-4,dn3/dt=4.65E-6
Wherein dn1/dt is the relative temperature variation of refractive index of the first eyeglass E1;
Wherein dn2/dt is the relative temperature variation of refractive index of the second eyeglass E2;
Wherein dn3/dt is the relative temperature variation of refractive index of prismatic glasses E3.Be described below with reference to the technique effect of chart, so that above-mentioned feature and advantage of the present utility model are clear more and understanding easily above-mentioned utility model.
In specific embodiment 1, the focal length of each eyeglass is as follows:
f1=-9.06;f2=31.46;f3=8.69;f4=11.21;f=3.03。
Along optical axis parallel from object space with each parts number consecutively; the minute surface of the first eyeglass E1 is S1, S2; the minute surface of the second eyeglass E2 is S3, S4; the minute surface of optical filter E5 is S5, S6; the face of diaphragm is S7, and the minute surface of prismatic glasses E3 is S8, S9, and the minute surface of the 4th eyeglass E4 is S10, S11; the minute surface of chip cover glass E7 is S12, S13, and the face of image planes is S14.
What table 1, table 2 were listed is the correlation parameter of the eyeglass of specific embodiment 1, comprises surface type, the radius-of-curvature of eyeglass face, also has thickness, material, effective diameter and the circular cone coefficient of each eyeglass.
Systematic parameter: 1/3 " sensor devices f-number 1.0
Table 1
| Face sequence number S | Surface type | Radius of curvature R | Thickness D | Material | Effective diameter D | The circular cone COEFFICIENT K |
| Object plane | Sphere | Infinite | 1500 | 3212.67 | ||
| S1 | Aspheric surface | 11.3542 | 1.5 | 1.531/56.0 | 12.70 | 0.0811 |
| S2 | Aspheric surface | 3.1964 | 6.3628 | 8.49 | -0.6338 | |
| S3 | Aspheric surface | -5.7885 | 4.575 | 1.531/56.0 | 6.92 | -0.3649 |
| S4 | Aspheric surface | -5.4490 | 0.0919 | 8.78 | -0.4237 | |
| S5 | Sphere | Infinite | 0.0832 | 7.73 | ||
| S6 | Sphere | Infinite | 0.7 | 1.517/64.2 | 7.87 | |
| S7 | Sphere | Infinite | 0.1264 | 8.15 | ||
| S8 | Sphere | 7.1267 | 3.6 | 1.804/46.6 | 9.30 | |
| S9 | Sphere | -145.1524 | 3.1342 | 9.30 | ||
| S10 | Aspheric surface | -49.7950 | 1.85 | 1.585/29.9 | 6.97 | 164.1206 |
| S11 | Aspheric surface | -5.7482 | 0.9399 | 7.31 | -5.7634 | |
| S12 | Sphere | Infinite | 0.75 | 1.517/64.2 | 6.91 | |
| S13 | Sphere | Infinite | 1.19 | 6.75 | ||
| S14 | Sphere | Infinite | 6.16 |
Table 2 is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, A16 of the aspherical lens of embodiment 1.
Table 2
| The face sequence number | A4 | A6 | A8 | A10 | A12 | A14 | A16 |
| S1 | 2.3362E-03 | -1.2134E-04 | 2.5030E-06 | -2.4976E-08 | 7.9173E-11 | -5.4554E-13 | 1.6517E-14 |
| S2 | 4.3314E-03 | 1.7707E-04 | -4.2477E-05 | 2.1039E-06 | -4.3143E-08 | -7.1926E-11 | -1.9559E-11 |
| S3 | -1.7167E-03 | -4.8984E-05 | -5.4706E-06 | 2.5763E-08 | -6.0404E-09 | -6.6963E-11 | 4.2800E-11 |
| S4 | -1.7078E-04 | -7.2242E-06 | -3.5677E-07 | 3.4687E-08 | -6.5824E-10 | -8.8487E-12 | 2.0660E-13 |
| S10 | -4.4378E-03 | -2.3426E-05 | -2.2179E-05 | 1.7702E-06 | 4.3139E-09 | 3.0210E-10 | -8.5061E-11 |
| S11 | -1.5712E-03 | -1.5702E-04 | 1.1127E-05 | -2.2575E-07 | 1.8733E-08 | -4.5588E-10 | 3.6891E-12 |
Fig. 2 to Fig. 8 is specific embodiment 1 corresponding optical performance curve figure.Fig. 2 to Fig. 5 has characterized the features such as aberration, astigmatism, distortion and ratio chromatism, of near infrared camera lens of the present utility model respectively, the near infrared camera lens that from figure, can clearly be seen that embodiment 1 of the present utility model at aspects such as aberration, astigmatism and distortion be improved significantly, image quality improves greatly.Fig. 6 to Fig. 8 is the corresponding FFTMTF figure of specific embodiment 1, in order to the reflection heat difference feature that disappears.Can know from Fig. 6 to Fig. 8 and find out that the near infrared camera lens of present embodiment 1 has the good heat difference performance that disappears.
Introduce the near infrared camera lens of embodiment 2 below further.The near infrared camera lens of embodiment 2 has adopted four set of contact lenses equally, and the diopter of each eyeglass, configuration, layout are identical with the near infrared camera lens of embodiment 1, but the concrete parameter of each eyeglass is diverse.
The focal length of each eyeglass of the near infrared camera lens of embodiment 2 is as follows:
f1=-6.80;f2=23.53;f3=6.53;f4=8.47;f=2.27。
The near infrared camera lens of embodiment 2 adopts glass to mould the structure of mixing equally, and it is poor that realization overcomes the heat that disappears.And described eyeglass satisfies following expression formula:
dn1/dt=dn2/dt=-1.022E-4,dn3/dt=4.65E-6
What table 3, table 4 were listed is the correlation parameter of the eyeglass of specific embodiment 2, comprises surface type, the radius-of-curvature of eyeglass face, also has thickness, material, effective diameter and the circular cone coefficient of each eyeglass.
Systematic parameter: 1/4 " sensor devices f-number 1.0
Table 3
| Face sequence number S | Surface type | Radius of curvature R | Thickness D | Material | Effective diameter D | The circular cone COEFFICIENT K |
| Object plane | Sphere | Infinite | 1500 | 3115.62 | ||
| ?S1 | Aspheric surface | 8.5032 | 1.1252 | 1.531/56.0 | 9.84 | 0.0828 |
| ?S2 | Aspheric surface | 2.3964 | 4.7657 | 6.32 | -0.6341 | |
| ?S3 | Aspheric surface | -4.3405 | 3.4350 | 1.531/56.0 | 5.20 | -0.3716 |
| ?S4 | Aspheric surface | -4.0844 | 0.0687 | 6.61 | -0.4228 | |
| ?S5 | Sphere | Infinite | 0.0638 | 5.79 | ||
| ?S6 | Sphere | Infinite | 0.7 | 1.517/64.2 | 5.90 | |
| ?S7 | Sphere | Infinite | 0.0993 | 6.13 | ||
| ?S8 | Sphere | 5.3498 | 2.7057 | 1.804/46.6 | 7.00 | |
| S9 | Sphere | -108.9019 | 2.3504 | 7.00 | ||
| S10 | Aspheric surface | -37.1690 | 1.3898 | 1.585/29.9 | 5.24 | 166.7381 |
| S11 | Aspheric surface | -4.3382 | 0.0750 | 5.51 | -5.7898 | |
| S12 | Sphere | Infinite | 0.75 | 1.517/64.2 | 5.21 | |
| S13 | Sphere | Infinite | 1.4021 | 5.05 | ||
| S14 | Sphere | Infinite | 4.54 |
Table 4 is aspheric surface high-order term coefficient A4, A6, A8, A10, A12, A14, A16 of the aspherical lens of embodiment 2.
Table 4
| The face sequence number | A4 | A6 | A8 | A10 | A12 | A14 | A16 |
| S1 | 5.5384E-03 | -5.1121E-04 | 1.8756E-05 | -3.3284E-07 | 1.8796E-09 | -2.2949E-11 | 1.2341E-12 |
| S2 | 1.0293E-02 | 7.4501E-04 | -3.1815E-04 | 2.8033E-05 | -1.0201E-06 | -3.0668E-09 | -1.4562E-09 |
| S3 | -4.0494E-03 | -2.0569E-04 | -4.0892E-05 | 3.3903E-07 | -1.4268E-07 | -3.0926E-09 | 3.2054E-09 |
| S4 | -4.0971E-04 | -3.1534E-05 | -2.7005E-06 | 4.6058E-07 | -1.5426E-08 | -3.8711E-10 | 1.5480E-11 |
| S10 | -1.0552E-02 | -1.0399E-04 | -1.6711E-04 | 2.3516E-05 | 1.0864E-07 | 1.4125E-08 | -6.4622E-09 |
| S11 | -3.7581E-03 | -6.7061E-04 | 8.2684E-05 | -3.0586E-06 | 4.4467E-07 | -1.9207E-08 | 2.0274E-10 |
Fig. 9 to Figure 15 is specific embodiment 2 corresponding optical performance curve figure.Fig. 9 to Figure 12 has characterized the features such as aberration, astigmatism, distortion and ratio chromatism, of the near infrared camera lens of embodiment 2 respectively, the near infrared camera lens that from figure, can clearly be seen that embodiment 2 of the present utility model at aspects such as aberration, astigmatism and distortion be improved significantly, image quality improves greatly.Figure 13 to Figure 15 is the corresponding FFT MTF figure of specific embodiment 2, in order to the reflection heat difference feature that disappears.Can know from Figure 13 to Figure 15 and find out that the near infrared camera lens of present embodiment 2 has the good heat difference performance that disappears.
More than data representation in the curve map of each optical property, the utility model near infrared camera lens has optical effect preferably, has realized large aperture, wide-angle, little distortion, the heat that disappears is poor.
Concrete parameter in the above table only is exemplary, and the value of each eyeglass composition radius-of-curvature, face interval and refractive index etc. are not limited to by the shown value of each numerical value of the foregoing description, can adopt other value, can reach the similar techniques effect.
Though described principle of the present utility model and embodiment at the near infrared camera lens above; but under above-mentioned instruction of the present utility model; those skilled in the art can carry out various improvement and distortion on the basis of the foregoing description, and these improvement or distortion all drop in the protection domain of the present utility model.It will be understood by those skilled in the art that top specific descriptions just in order to explain the purpose of this utility model, and be not to be used to limit the utility model that protection domain of the present utility model is limited by claim and equivalent thereof.
Claims (7)
1. near infrared camera lens, this camera lens comprises four set of contact lenses from the object side to the image side successively along optical axis, and first eyeglass is the falcate eyeglass of negative power, and convex surface adopts aspheric surface towards object space; Second eyeglass is the falcate eyeglass of plus or minus focal power, and convex surface is towards picture side; Prismatic glasses is lenticular, the convexo-plane or the falcate eyeglass of positive light coke, and when plano-convex or falcate, convex surface is towards object space; The 4th eyeglass is the eyeglass of positive light coke, adopts aspheric surface.
2. near infrared camera lens according to claim 1 is characterized in that, described near infrared camera lens satisfies following relational expression:
①-0.5<f/f1<-0.2
Wherein f1 is the focal length of first eyeglass, and f is the focal length of total system;
②|f2|>|f1|
Wherein | f1| is the absolute value of the focal length of first eyeglass, | f2| is the absolute value of the focal length of second eyeglass;
③f4>f3
Wherein f3 is the focal length of prismatic glasses, and f4 is the focal length of the 4th eyeglass;
④0.2<f/f3<0.6
Wherein f3 is the focal length of prismatic glasses, and f is the focal length of total system.
3. near infrared camera lens according to claim 1 and 2 is characterized in that, described near infrared camera lens also comprises diaphragm, and described diaphragm is between described second eyeglass and prismatic glasses.
4. near infrared camera lens according to claim 1 and 2 is characterized in that, described near infrared camera lens satisfies following relational expression:
0<dn3/dt<1E-05,-1E-3<dn1/dt<-5E-5,-1E-3<dn2/dt<-5E-5
Wherein dn1/dt is the relative temperature variation of refractive index of first eyeglass;
Wherein dn2/dt is the relative temperature variation of refractive index of second eyeglass;
Wherein dn3/dt is the relative temperature variation of refractive index of the 3rd eyeglass.
5. near infrared camera lens according to claim 1 is characterized in that described prismatic glasses is a glass mirror, and described first and second and four eyeglasses are glass lens.
6. near infrared camera lens according to claim 1 is characterized in that, described near infrared camera lens also comprises optical filter, and described optical filter is arranged between second eyeglass and the prismatic glasses.
7. near infrared camera lens according to claim 1 is characterized in that, the stationkeeping of each eyeglass.
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| Application Number | Priority Date | Filing Date | Title |
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| CN2011202182398U CN202093231U (en) | 2011-06-24 | 2011-06-24 | Near-infrared camera lenses |
| PCT/CN2011/078488 WO2012174786A1 (en) | 2011-06-24 | 2011-08-16 | Near infrared lens |
| US13/501,053 US9229201B2 (en) | 2011-06-24 | 2011-08-16 | Near infrared lens |
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| CN2011202182398U CN202093231U (en) | 2011-06-24 | 2011-06-24 | Near-infrared camera lenses |
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| CN102213821A (en) * | 2011-06-24 | 2011-10-12 | 浙江舜宇光学有限公司 | Near infrared lens |
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| CN102213821A (en) * | 2011-06-24 | 2011-10-12 | 浙江舜宇光学有限公司 | Near infrared lens |
| CN102213821B (en) * | 2011-06-24 | 2013-04-10 | 浙江舜宇光学有限公司 | Near infrared lens |
| US9354425B2 (en) | 2014-03-10 | 2016-05-31 | Largan Precision Co., Ltd. | Wide-angle image capturing lens assembly, image capturing device and vehicle device |
| CN104238117A (en) * | 2014-10-09 | 2014-12-24 | 中山联合光电科技有限公司 | Low-cost low-temperature-drift infrared optical confocal system |
| CN106468815B (en) * | 2016-07-05 | 2019-07-26 | 玉晶光电(厦门)有限公司 | Optical imaging lens |
| CN106468816A (en) * | 2016-07-05 | 2017-03-01 | 玉晶光电(厦门)有限公司 | Optical imaging lens |
| CN106468815A (en) * | 2016-07-05 | 2017-03-01 | 玉晶光电(厦门)有限公司 | Optical imaging lens |
| CN106468814A (en) * | 2016-07-05 | 2017-03-01 | 玉晶光电(厦门)有限公司 | Optical glass group |
| US11009680B2 (en) | 2017-04-24 | 2021-05-18 | Zhejiang Sunny Optical Co., Ltd | Iris lens assembly |
| CN107121755A (en) * | 2017-06-19 | 2017-09-01 | 南京华捷艾米软件科技有限公司 | A kind of infrared lens measured for 3D |
| CN107121755B (en) * | 2017-06-19 | 2020-08-21 | 南京华捷艾米软件科技有限公司 | Infrared lens for 3D measurement |
| US11163134B2 (en) | 2018-12-20 | 2021-11-02 | Largan Precision Co., Ltd. | Imaging lens system, identification module and electronic device |
| US11327277B2 (en) | 2019-11-29 | 2022-05-10 | Largan Precision Co., Ltd. | Lens system and electronic device |
| US11640046B2 (en) | 2019-11-29 | 2023-05-02 | Largan Precision Co., Ltd. | Lens system and electronic device |
| US11940598B2 (en) | 2019-11-29 | 2024-03-26 | Largan Precision Co., Ltd. | Lens system and electronic device |
| CN111061044A (en) * | 2020-01-08 | 2020-04-24 | 武汉高德智感科技有限公司 | Infrared wide-angle lens and camera equipment |
| WO2022110208A1 (en) * | 2020-11-30 | 2022-06-02 | 欧菲光集团股份有限公司 | Optical lens, camera module and electronic device |
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