CN108681032A - A kind of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens - Google Patents

Abstract

The invention discloses a kind of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lenses, include the first lens being arranged in order from object side to target surface, the second lens, the third lens and the 4th lens；Wherein, the first lens are the negative-power lenses convex surface facing object side；Second lens are the positive power lens convex surface facing object side；The third lens are the negative-power lenses convex surface facing object side；4th lens are the positive power lens convex surface facing object side.The present invention uses PASSIVE OPTICAL athermal technology, diagonal angles of visual field that can reach 180 °, and it is high to be suitable for the larger occasion of range of temperature, the reliabilities such as forest fire protection monitoring, public security, frontier defense warning for 40 °~+60 ° of range of temperature；It is big to be imaged breadth, can be used for 640 movements, optical system thang-kng amount is big.

Description

A kind of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens

Technical field

The present invention relates to a kind of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lenses, belong to passive athermal flake Camera lens field.

Background technology

LONG WAVE INFRARED fish eye lens is the special lens that a kind of field angle can reach 180 degree or more, monitor in forest fire protection, Public security, frontier defense warning etc. play an important roll, big in these special occasions range of temperature, lead to optical system target surface Decline with temperature drift image quality, it is necessary to which athermal design is used to optical system；

106547074 A of CN disclose a kind of infrared fish eye lens of five chips；CN204462517 U disclose one kind three 150 degree of flake LONG WAVE INFRARED camera lenses of chip, both of the above is all without reference to PASSIVE OPTICAL athermal technology；

The athermal lens field angle announced in the prior art is smaller or movement target surface is small, such as：CN 103852863A are announced Field angle be about 35 °；The field angle that CN103995344A is announced is about 15.24 ° x11.46 °；106405800 A of CN are announced Detector：LWIR Uncooled type 160*120,25um, 43 ° x32 ° of field angle.

The passive athermal infrared optical lens of wide angle optical and in October, 2014 that 201096959 Y of CN are announced are paid Jump just et al.《Infrared and laser engineering》It is delivered on Vol.43No.10《The infrared fish eye optical systems of two waveband athermal are set Meter》It is directed to refrigeration mode movement to design, to ensure 100% cold stop efficiency, by the cold screen weight of the aperture diaphragm of system and movement It closes.With being constantly progressive for technology, non-brake method LONG WAVE INFRARED movement develops towards the high pixel of big target surface, while with field angle and phase Increase to aperture, big visual field differ greatly with small field of view light path track, lead to big target surface LONG WAVE INFRARED FISH EYE LENS OPTICS quilt Dynamic athermal difficulty is larger, Fu Yuegang et al.《The infrared fish eye optical systems design of two waveband athermal》The F numbers of institute's public address system (focal length/system aperture) is 2.68, has used 7 lens, image quality evaluation general.

Invention content

In order to solve the defects of athermal lens field angle is smaller in the prior art or movement target surface is small, the present invention provides one Kind large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens, is that a kind of large format suitable for the infrared movements of 640x480 is long The passive athermal fish eye lens of wave infrared optics, the application give a kind of big target surface LONG WAVE INFRARED FISH EYE LENS OPTICS and passively disappear Heat differential solution is suitable for the larger occasions of range of temperature such as forest fire protection monitoring, public security, frontier defense warning.

In order to solve the above technical problems, the technical solution adopted in the present invention is as follows：

A kind of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens includes be arranged in order from object side to target surface One lens, the second lens, the third lens and the 4th lens；

Wherein, the first lens are the negative-power lenses convex surface facing object side；

Second lens are the positive power lens convex surface facing object side；

The third lens are the negative-power lenses convex surface facing object side；

4th lens are the positive power lens convex surface facing object side.

Above-mentioned large format LONG WAVE INFRARED PASSIVE OPTICAL athermal flake mirror efficiently solves athermal lens in the prior art The defects of field angle is smaller or movement target surface is small.

Further, infrared fish eye lens focal length f ' is shorter, and to ensure back work distance from BFL, the application is taken the photograph far using counter Structure meets：BFL/f’>1.4；-3<f1’/f’<0；2<f2’/f’<4；Wherein, f1 ' is the focal length of the first lens；F2 ' is Two, the combined focal length of three, four lens；F ' is camera lens combined focal length；BFL be back work distance from.

Back work distance is referred to as counter more than the optical system of focal length to take the photograph remote type structure.

Further, it is aberration correction and eliminates the influence of temperature change, using germanium and chalcogenide glass material mating, first Lens use high refractive index germanite glass, are conducive to aberration correction, while conveniently plating hard carbon films in front surface；Second lens, third Lens and the 4th lens are all made of the chalcogenide glass with relatively low refractive index temperature variation coefficient dn/dT, become for eliminating temperature Change the adverse effect to image quality.

Further, the applicable service band of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens is 8-12um.Light The F numbers of system are equal to 1.0 (F/#=1.0), and F/#=f '/D, wherein f ' are system focal length, and D is system aperture diaphragm diameter, F Number more mini system thang-kng amount is bigger.Diagonal angles of visual field is not less than 180 °, -40 °~+60 ° of range of temperature.

From the object side to the image side, the two sides of the first lens L1 is followed successively by object side S1 and image side surface S2 to above-mentioned camera lens；Second thoroughly The two sides of mirror L2 is followed successively by object side S3 and image side surface S4；The two sides of the third lens L3 is followed successively by object side S5 and image side surface S6； The two sides of 4th lens L4 is followed successively by object side S7 and image side surface S8；Object side S1 is spherical surface, and image side surface S2 is aspherical；Object side Face S3 is aspherical, and image side surface S4 is diffraction surfaces；Object side S5 is aspherical, and image side surface S6 is aspherical；Object side S7 is non- Spherical surface, image side surface S8 are aspherical.

In order to further ensure field angle and athermal effect, it is preferable that the radius of curvature of object side S1 be 61.43mm or The radius of curvature of 36.24mm, image side surface S2 are 24.01mm or 19.38mm；The radius of curvature of object side S3 be 29.89mm or The radius of curvature of 25.94mm, image side surface S4 are 1537.76mm or 53.75mm；The radius of curvature of object side S5 is -326.32mm Or the radius of curvature of 37.32mm, image side surface S6 are 37.17mm or 40.22mm；The radius of curvature of object side S7 be 27.69mm or The radius of curvature of 50.08mm, image side surface S8 are 82.02mm or 65.38mm.

In order to further ensure field angle, it is preferable that the outer diameter of object side S1 is 42mm or 52mm, and the outer diameter of image side surface S2 is 30mm or 38mm；The outer diameter of object side S3 is 30mm or 30mm, and the outer diameter of image side surface S4 is 30mm or 27mm；Object side S5's is outer Diameter is 22mm or 22mm, and the outer diameter of image side surface S6 is 19mm or 21mm；The outer diameter of object side S7 is 19mm or 23mm, image side surface S8 Outer radius be 22mm or 23mm.

The outer diameter of each each side of lens refers to outer circle (round edge) diameter of each lens.

In order to further ensure imaging effect, it is preferable that the center thickness of the first lens is 5mm or 2.5mm, the second lens Center thickness is 8mm, and the center thickness of the third lens is 2.5mm, and the center thickness of the 4th lens is 3.7mm or 5.3mm；First 44.2mm or 54.3mm is divided between lens and the second lens；It is divided into 7.5mm between second lens and the third lens Or 14.5mm；It is divided into 5mm or 1.7mm between the third lens and the 4th lens.

Above-mentioned interval refers to the spacing between the center of the two adjacent surfaces of adjacent two lens.

The unmentioned technology of the present invention is with reference to the prior art.

Compared with prior art, the present invention having following advantage：

1. using PASSIVE OPTICAL athermal technology, system F numbers are equal to 1.0, and thang-kng amount is big；Diagonal angles of visual field can reach 180 °, -40 °~+60 ° of range of temperature, be suitable for forest fire protection monitoring, public security, frontier defense warning etc. range of temperature compared with Big occasion, reliability are high；

2. it is big to be imaged breadth, it can be used for 640 movement of non-refrigeration type, optical system thang-kng amount is big；

3. further, first uses germanium, facilitate plating hard carbon films；Three pieces use chalcogenide glass afterwards, have in material cost There is an apparent advantage, when mass production can carry out accurate die pressing, can reduce processing cost, wide market.

Description of the drawings

Fig. 1 is the 1 fish-eye structural schematic diagram of LONG WAVE INFRARED athermal of specific embodiment；

Fig. 2 is MTF curve figure of the specific embodiment 1 at 20 °；

Fig. 3 is MTF curve figure of the specific embodiment 1 at -40 °；

Fig. 4 is MTF curve figure of the specific embodiment 1 at 60 °；

Fig. 5 is the curvature of field and distortion figure of the specific embodiment 1 at 20 °；

Fig. 6 is the 2 fish-eye structural schematic diagram of LONG WAVE INFRARED athermal of specific embodiment；

Fig. 7 is MTF curve figure of the specific embodiment 2 at 20 °；

Fig. 8 is MTF curve figure of the specific embodiment 2 at -40 °；

Fig. 9 is MTF curve figure of the specific embodiment 2 at 60 °；

Figure 10 is the curvature of field and distortion figure of the specific embodiment 2 at 20 °；

Specific implementation mode

For a better understanding of the present invention, with reference to the embodiment content that the present invention is furture elucidated, but the present invention Content is not limited solely to the following examples.

Embodiment 1

Embodiment 1 is applicable in wave band 8-12um, F number 1.0,180 ° of diagonal angles of visual field

Large format LONG WAVE INFRARED athermal fish eye lens as shown in Figure 1, is arranged in order along optical axis OO ' from object to image space： The first lens L1 with negative power, the second lens L2 with positive light coke, the third lens L3 with negative power, tool There are the 4th lens L4 and imaging surface S9 of positive light coke.

From the object side to the image side, the two sides of the first lens L1 is object side S1, image side surface S2；The two sides of second lens L2 is object Side S3, image side surface S4；The two sides of the third lens L3 is object side S5, image side surface S6；4th two sides lens L4 be object side S7, Image side surface S8；

First lens L1 uses germanium, the high refractive index of germanium to contribute to aberration correction up to 4.0, facilitate plating hard carbon films in technique；

Second and third, four lens use chalcogenide glass, it is smaller that chalcogenide glass refractive index varies with temperature coefficient d n/dT, in light Good athermal function may be implemented plus the distribution of rational focal power using chalcogenide glass in system.In material cost With apparent advantage, when mass production, can carry out accurate die pressing, can reduce processing cost, wide market.

Above-mentioned optical system focal length f ' is shorter, is taken the photograph remote structure using counter and is ensured that back work distance from BFL, needs to meet

BFL/f’>1.4；

-3<f1’/f’<0；

2<f2’/f’<4

Wherein, f1 ' is the focal length of the first lens；F2 ' is second and third, the combined focal lengths of four lens；F ' is lens group focus Away from；

Fig. 2 to Fig. 4 be above-mentioned optical system in -40 ° of temperature ,+20 ° ,+60 ° of optical transfer function curve graphs, represent optics For the synthesis solution that system varies with temperature as horizontal, cooperation 17 μm of (Pixel Dimensions) request detectors of 640x480 reach 30 lines to dividing Resolution；The LONG WAVE INFRARED optical system is by various optical aberration correctings as seen from the figure, it is sufficient to meet the requirement of PASSIVE OPTICAL athermal.Figure 5 be the curvature of field and distortion figure of the embodiment, and the curvature of field is less than 0.05mm, distortion 100%.

The design parameter of 1 embodiment 1 of table

Minute surface serial number in upper table is corresponding with the minute surface serial number in Fig. 1；The center that the corresponding spacing of S1 refers to lens L1 is thick Degree, the corresponding spacing of S2 refer to the spacing between the center of S2 and the center of S3, and the corresponding spacing of S3 refers to the center thickness of L2, S4 pairs The spacing answered refers to the spacing between the center of S4 and the center of S5, and the corresponding spacing of S5 refers to the center thickness of L3, corresponding of S6 Away from the spacing between the center and the center of S7 for referring to S6, the corresponding spacing of S7 refers to the center thickness of L4, and the corresponding spacing of S8 refers to S8 Center and the center of S9 between spacing；Outer diameter refers to the outside diameter of each minute surface；

The aspherical equation used in table 1：

The meaning wherein respectively measured is as follows：

ZA：The aspherical lens rise along optical axis direction；

R：The radius of curvature on surface and optical axis OO ' point of intersection；

Y：Vertical lens are in half bore of optical axis direction；

k：Circular cone coefficient；

A, the face B, C, D, E coefficient；Specific coefficient is shown in Table 2

2 embodiment of table, 1 asphericity coefficient

It is aspherical

K

A

B

C

D

E

S2

0

6.1524E-06

1.4483E-08

4.0109E-11

-1.0301E-14

0.0000E+00

S3

0

-3.0638E-06

-3.1206E-09

-1.4950E-11

2.3336E-14

-7.2790E-17

S4

0

6.0031E-06

-3.1708E-08

3.0993E-12

-4.1018E-14

1.0558E-16

S5

0

3.5979E-05

5.7854E-07

-1.7845E-09

4.2412E-12

6.2941E-15

S6

0

-2.1740E-07

3.7535E-07

-1.6010E-09

4.7633E-12

-2.3518E-14

S7

0

-1.7351E-05

-2.1554E-07

-3.4582E-09

-4.5131E-11

4.0909E-15

S8

0

-2.3900E-07

-5.9903E-07

-4.4707E-09

4.1554E-11

1.7745E-15

Table 3 is the diffraction surfaces coefficient of embodiment 1

Diffraction surfaces equation used by table 1 is：

Φ=A₁Y²+A₂Y⁴+A₃Y⁶

Wherein：

Φ：For the position phase of diffraction surfaces；

Y：Vertical lens are in half bore of optical axis direction；

A1, A2, A3 diffraction surfaces phase coefficient.

Embodiment 2

As shown in fig. 6, it is substantially the same manner as Example 1, except that：When field angle further increases, increase by first The curvature of lens L1, the present embodiment diagonal angles of visual field can reach 184 °, wave band 8-12um, F number 1.0.

The design parameter of 4 embodiment 2 of table

Minute surface serial number in upper table is corresponding with the minute surface serial number in Fig. 6；The center that the corresponding spacing of S1 refers to lens L1 is thick Degree, the corresponding spacing of S2 refer to the spacing between the center of S2 and the center of S3, and the corresponding spacing of S3 refers to the center thickness of L2, S4 pairs The spacing answered refers to the spacing between the center of S4 and the center of S5, and the corresponding spacing of S5 refers to the center thickness of L3, corresponding of S6 Away from the spacing between the center and the center of S7 for referring to S6, the corresponding spacing of S7 refers to the center thickness of L4, and the corresponding spacing of S8 refers to S8 Center and the center of S9 between spacing；Outer diameter refers to the outside diameter of each minute surface；

The aspherical equation used in table 4：

The meaning wherein respectively measured is as follows：

ZA：The aspherical lens rise along optical axis direction；

R：The radius of curvature on surface and optical axis OO ' point of intersection；

Y：Vertical lens are in half bore of optical axis direction；

k：Circular cone coefficient；

A, the face B, C, D, E coefficient；Specific coefficient is shown in Table 5

Table 5

It is aspherical

K

A

B

C

D

E

S2

0

-7.5441E-07

7.2758E-08

-3.0958E-10

2.8644E-13

-3.7771E-16

S3

0

3.2900E-06

-6.6684E-11

-3.5349E-11

5.2302E-13

-7.7637E-16

S4

0

2.5551E-06

-5.0328E-08

6.7899E-12

-3.7085E-15

-1.0221E-15

S5

0

-1.0902E-05

-5.1116E-07

-1.0263E-09

2.3462E-11

-9.0051E-14

S6

0

-8.5944E-07

-6.7085E-07

1.7643E-09

-4.4825E-12

9.2697E-14

S7

0

4.7857E-05

-1.1506E-07

-1.2690E-09

-6.1174E-12

5.2086E-17

S8

0

-6.3695E-06

-4.5595E-08

-4.2723E-09

1.4049E-11

1.6082E-16

4 specific embodiment two of table is shown in Table 6 using diffraction surfaces coefficient

Table 6 is the diffraction surfaces coefficient of embodiment 2

Diffraction surfaces equation used by embodiment 2 is：

Φ=A₁Y²+A₂Y⁴+A₃Y⁶

Wherein：

Φ：For the position phase of diffraction surfaces；

Y：Vertical lens are in half bore of optical axis direction；

A1, A2, A3 diffraction surfaces phase coefficient.

Fig. 7 to Fig. 8 is 2 optical system of embodiment in -40 ° of temperature ,+20 ° ,+60 ° of optical transfer function curve graphs, representative For the comprehensive solution that optical system varies with temperature as horizontal, cooperation 17 μm of request detectors of 640x480 reach 30 lines to resolution ratio； The LONG WAVE INFRARED optical system is by various optical aberration correctings as seen from the figure, it is sufficient to meet the requirement of PASSIVE OPTICAL athermal.Figure 10 is The curvature of field and distortion figure of the embodiment, the curvature of field are less than 0.1mm, distortion 100%.

Claims (10)

1. a kind of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens, it is characterised in that：Including from object side to target surface according to The first lens, the second lens, the third lens and the 4th lens of secondary arrangement；

Wherein, the first lens are the negative-power lenses convex surface facing object side；

Second lens are the positive power lens convex surface facing object side；

The third lens are the negative-power lenses convex surface facing object side；

4th lens are the positive power lens convex surface facing object side.

2. large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as described in claim 1, it is characterised in that：Using anti- Take the photograph remote structure.

3. large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as claimed in claim 2, it is characterised in that：Meet： BFL/f’>1.4；-3<f1’/f’<0；2<f2’/f’<4；Wherein, f1 ' is the focal length of the first lens；F2 ' is second and third, four thoroughly The combined focal length of mirror；F ' is camera lens combined focal length；BFL be back work distance from.

4. the large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as described in claim 1-3 any one, feature It is：First lens use germanite glass；Second lens, the third lens and the 4th lens are all made of chalcogenide glass.

5. the large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as described in claim 1-3 any one, feature It is：The fish-eye service band of large format LONG WAVE INFRARED PASSIVE OPTICAL athermal is 8-12um.

6. the large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as described in claim 1-3 any one, feature It is：The F numbers of optical system are equal to 1.0, and diagonal angles of visual field is not less than 180 °, -40 °~+60 ° of range of temperature.

7. the large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as described in claim 1-3 any one, feature It is：From the object side to the image side, the two sides of the first lens L1 is followed successively by object side S1 and image side surface S2；The two sides of second lens L2 according to Secondary is object side S3 and image side surface S4；The two sides of the third lens L3 is followed successively by object side S5 and image side surface S6；4th lens L4's Two sides is followed successively by object side S7 and image side surface S8；Object side S1 is spherical surface, and image side surface S2 is aspherical；Object side S3 is aspheric Face, image side surface S4 are diffraction surfaces；Object side S5 is aspherical, and image side surface S6 is aspherical；Object side S7 is aspherical, image side surface S8 is aspherical.

8. large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as claimed in claim 7, it is characterised in that：Object side The radius of curvature of S1 is 61.43mm or 36.24mm, and the radius of curvature of image side surface S2 is 24.01mm or 19.38mm；Object side S3 Radius of curvature be 29.89mm or 25.94mm, the radius of curvature of image side surface S4 is 1537.76mm or 53.75mm；Object side S5 Radius of curvature be -326.32mm or 37.32mm, the radius of curvature of image side surface S6 is 37.17mm or 40.22mm；Object side S7 Radius of curvature be 27.69mm or 50.08mm, the radius of curvature of image side surface S8 is 82.02mm or 65.38mm.

9. large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as claimed in claim 7, it is characterised in that：Object side The outer diameter of S1 is 42mm or 52mm, and the outer diameter of image side surface S2 is 30mm or 38mm；The outer diameter of object side S3 is 30mm or 30mm, as The outer diameter of side S4 is 30mm or 27mm；The outer diameter of object side S5 is 22mm or 22mm, the outer diameter of image side surface S6 be 19mm or 21mm；The outer diameter of object side S7 is 19mm or 23mm, and the outer radius of image side surface S8 is 22mm or 23mm.

10. the large format LONG WAVE INFRARED PASSIVE OPTICAL athermal fish eye lens as described in claim 1-3 any one, feature It is：The center thickness of first lens is 5mm or 2.5mm, and the center thickness of the second lens is 8mm, and the center of the third lens is thick Degree is 2.5mm, and the center thickness of the 4th lens is 3.7mm or 5.3mm；It is divided between first lens and the second lens 44.2mm or 54.3mm；7.5mm or 14.5mm is divided between second lens and the third lens；The third lens and the 4th lens Between between be divided into 5mm or 1.7mm.