CN205210401U - Dual -purpose monitoring camera of day night - Google Patents
Dual -purpose monitoring camera of day night Download PDFInfo
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- CN205210401U CN205210401U CN201520943446.8U CN201520943446U CN205210401U CN 205210401 U CN205210401 U CN 205210401U CN 201520943446 U CN201520943446 U CN 201520943446U CN 205210401 U CN205210401 U CN 205210401U
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Abstract
The utility model provides a dual -purpose monitoring camera of day night has set gradually first lens, second lens, third lens and fourth lens from the object space to the image space, first lens are negative focal length aspherical mirror piece, and the second lens are positive focus biconvex type spheric glass, and the third lens are positive focus biconvex type aspherical mirror piece, and the fourth lens are negative focal length aspherical mirror piece, wherein, the focus of first lens is f1, and the focus of fourth lens is f4, has 1.227< F1f4< 1.44. First lens are negative focal length plastic aspherical mirror piece, and the second lens are positive focus biconvex type glass spheric glass, and the third lens are positive focus biconvex type plastic aspherical mirror piece. The utility model discloses owing to used plastic aspherical mirror piece for the cost of manufacture of camera lens can reduce, has improved the product competitiveness, and, solved the bad problem of high low temperature analysis because of using plastic aspherical mirror piece to result in, increased the use occasion and the ambient condition scope of product.
Description
Technical field
The utility model relates to optical field, particularly a kind of day and night monitoring camera.
Background technology
Along with the development of science and technology, the technological breakthrough of mould manufacturer, it is relatively low to add plastic lens price, and Phytolacca acinosa continuous plastic lens of bringing into use in optical instrument factory's replaces glass mirror, to improve the competitive power of camera lens; Existing day and night monitoring camera, the full glass mirror of many uses, or glass moulds the structure of eyeglass mixing, reaches lens performance requirement.
Chinese patent literature CN204215091U disclosed a kind of 6mm day and night tight shot on 03 18th, 2015, comprise the first lens of the convex-concave negative power set gradually along light direction, the second lens of concavo-convex positive light coke, 3rd lens of biconvex positive light coke, 4th lens of concave-concave negative power, the 5th lens of biconvex positive light coke; The radius-of-curvature of the focal length of five lens of this camera lens, refractive index and totally ten curved surfaces meets certain condition respectively.
Chinese patent literature CN204178034U disclosed a kind of optical system on 02 25th, 2015, was provided with the first lens, the second lens, the 3rd lens and the 4th lens from the object side to the image side successively; The focal length of the first lens is negative value, the focal length of the second lens be on the occasion of the focal length of, the 3rd lens be on the occasion of, the focal length of the 4th lens is negative value; Diaphragm is provided with between the second lens and the 3rd lens; Described 3rd lens and described 4th lens adopt plastic cement aspherical lens; First lens, the second lens, the 3rd lens and the focal length of the 4th lens meet some requirements respectively with the ratio of the focal length of whole camera lens.
But the spinoff using plastic lens easily to bring is exactly: the focus drifting problem brought because thermal expansivity is comparatively large.
Utility model content
The purpose of this utility model aims to provide a kind of simple and reasonable, day and night monitoring camera that cost of manufacture is low, to overcome weak point of the prior art.
By a kind of day and night monitoring camera that this object designs, be disposed with the first lens, the second lens, the 3rd lens and the 4th lens from the object side to the image side, its architectural feature is described first lens is negative focal length aspherical lens, second lens are positive focal length biconvex spheric glass, 3rd lens are positive focal length biconvex aspherical lens, and the 4th lens are negative focal length aspherical lens; Wherein, the focal length of described first lens is f1, and the focal length of the 4th lens is f4, has 1.227<f1/f4<1.44.
Further, described first lens are negative focal length plastic cement aspherical lens, and the second lens are positive focal length biconvex glass spheric glass, and the 3rd lens are positive focal length biconvex plastic cement aspherical lens, and the 4th lens are negative focal length plastic cement aspherical lens.
Further, the focal length of described second lens is f2, and the focal length of the 3rd lens is f3, has 1.632<f2/f3<2.603.
Further, the focal length of described first lens is f1, and the focal length of the second lens is f2, has-0.928<f1/f2<-0.627.
Further, the focal length of described 3rd lens is f3, and the focal length of the 4th lens is f4, has-0.951<f3/f4<-0.752.
Further, diaphragm is provided with between described first lens and the second lens.
The first lens in the utility model, the 3rd lens and the 4th lens are plastic cement aspherical lens, second lens are glass spheric glass, ensureing on the basis that day and night mega pixel is resolved, only use a slice glass mirror and three plastic lens just to solve thermal drift problem and achieve athermal design, improve the camera lens market competitiveness.
The utility model adopts glass to mould eyeglass mix and match structure, adopts four eyeglasses, under the prerequisite of guarantee mega pixel image quality, and still has at near-infrared band and well resolves quality.
The utility model is owing to employing multi-disc plastic lens, and camera lens cost is minimized; Although because plastic lens temperature expansion coefficient is comparatively large, easily causes focus drifting under high and low temperature environment, thus cause analytic fuzzy; But the utility model passes through the positive negative focal length of reasonable distribution glass mirror and plastic lens, and aberration can be made to be corrected preferably, solve the problem that high/low temperature resolves focus drifting, make applied environment scope expanded, improve the market competitiveness.
In sum, the utility model, owing to employing plastic cement aspherical lens, makes the cost of manufacture of camera lens be minimized, improves product competitiveness; Further, solve the high/low temperature caused because using plastic cement aspherical lens and resolve bad problem, add use occasion and the range of environmental conditions of product.
Accompanying drawing explanation
Fig. 1 is the utility model one example structure schematic diagram.
Fig. 2 is the visible ray analysis diagram of the first application examples.
Fig. 3 is the near infrared light analysis diagram of the first application examples.
Fig. 4 is the Spot figure of the first application examples.
Fig. 5 is the field distortion figure of the first application examples.
Fig. 6 is the low temperature of the first application examples: analysis diagram when-20 degrees Celsius.
Fig. 7 is the high temperature of the first application examples: analysis diagram when 60 degrees Celsius.
Fig. 8 is the visible ray analysis diagram of the second application examples.
Fig. 9 is the near infrared light analysis diagram of the second application examples.
Figure 10 is the Spot figure of the second application examples.
Figure 11 is the field distortion figure of the second application examples.
Figure 12 is the low temperature of the second application examples: analysis diagram when-20 degrees Celsius.
Figure 13 is the high temperature of the second application examples: analysis diagram when 60 degrees Celsius.
Figure 14 is the visible ray analysis diagram of the 3rd application examples.
Figure 15 is the near infrared light analysis diagram of the 3rd application examples.
Figure 16 is the Spot figure of the 3rd application examples.
Figure 17 is the field distortion figure of the 3rd application examples.
Figure 18 is the low temperature of the 3rd application examples: analysis diagram when-20 degrees Celsius.
Figure 19 is the high temperature of the 3rd application examples: analysis diagram when 60 degrees Celsius.
In figure: L1 is the first lens, L2 is the second lens, and L3 is the 3rd lens, and L4 is the 4th lens, and 10 is diaphragm.
Embodiment
Below in conjunction with drawings and Examples, the utility model is further described.
See Fig. 1, this day and night monitoring camera, be disposed with the first lens L1, the second lens L2, the 3rd lens L3 and the 4th lens L4 from the object side to the image side, described first lens L1 is negative focal length aspherical lens, second lens L2 is positive focal length biconvex spheric glass, 3rd lens L3 is positive focal length biconvex aspherical lens, and the 4th lens L4 is negative focal length aspherical lens; Wherein, the focal length of described first lens L1 is f1, and the focal length of the 4th lens L4 is f4, has 1.227<f1/f4<1.44.
In the present embodiment, described first lens L1 is negative focal length plastic cement aspherical lens, second lens L2 is positive focal length biconvex glass spheric glass, and the 3rd lens L3 is positive focal length biconvex plastic cement aspherical lens, and the 4th lens L4 is negative focal length plastic cement aspherical lens.
The focal length of described second lens L2 is f2, and the focal length of the 3rd lens L3 is f3, has 1.632<f2/f3<2.603.
The focal length of described first lens L1 is f1, and the focal length of the second lens L2 is f2, has-0.928<f1/f2<-0.627.
The focal length of described 3rd lens L3 is f3, and the focal length of the 4th lens L4 is f4, has-0.951<f3/f4<-0.752.
Diaphragm 10 is provided with between described first lens L1 and the second lens L2.
First application examples
See Fig. 2-Fig. 7, should in use-case, the focal distance f=3.73mm of day and night monitoring camera, aperture F#=2.3, field angle FOV=108 °, focal length and the mutual relationship thereof of each eyeglass are as shown in the table:
f1 | f2 | f3 | f4 | f1/f2 | f3/f4 | f2/f3 | f1/f4 |
-6.42 | 10.24 | 3.931 | -5.23 | -0.627 | -0.752 | 2.60392 | 1.22753 |
Wherein, S1 is the front surface of the first lens L1, and S2 is the rear surface of the first lens L1, S3 is the surface of diaphragm 10, S4 is the front surface of the second lens L2, and S5 is the rear surface of the second lens L2, and S6 is the front surface of the 3rd lens L3, S7 is the rear surface of the 3rd lens L3, S8 is the front surface of the 4th lens L4, and S9 is the rear surface of the 4th lens L4, and S10 is the front surface of filter IRcut, S11 is the rear surface of filter IRcut, and S12 is the front surface of image planes imagePlane.
K | A | B | C | D | E | F | |
S1 | 3.478 | -5.41E-04 | -2.36E-04 | 1.02E-05 | 1.85E-07 | -1.53E-08 | 3.82E-11 |
S2 | -0.496 | -8.85E-04 | 1.65E-04 | -2.03E-04 | 1.93E-05 | 1.59E-06 | -1.68E-07 |
S4 | -9.426 | 1.00E-02 | -1.63E-03 | 2.54E-04 | -3.21E-05 | 2.62E-06 | -1.19E-07 |
S5 | -2.802 | 2.69E-03 | -3.82E-04 | -2.22E-05 | 1.40E-05 | -1.69E-06 | 5.68E-08 |
S8 | -2.54 | 1.53E-02 | -2.74E-03 | 2.06E-04 | 9.82E-06 | -2.54E-06 | 1.24E-07 |
S9 | -9.267 | 0.0201 | -2.03E-03 | 8.78E-05 | 5.20E-06 | -5.99E-07 | 1.95E-08 |
Wherein used asphericity coefficient adopts following computing formula:
In formula, r is the distance a bit to optical axis on optical surface, and Z is this rise along optical axis direction, and c is the curvature on this surface, and K is the quadric surface constant on this surface, and A ~ F is non-spherical repairing positive coefficient.
Second application examples
See Fig. 8-Figure 13, should in use-case, the f=3.7mm of day and night monitoring camera, F#=2.3, FOV=108 °; Focal length and the mutual relationship thereof of each eyeglass are as shown in the table:
f1 | f2 | f3 | f4 | f1/f2 | f3/f4 | f2/f3 | f1/f4 |
-6.28 | 9.632 | 3.899 | -4.893 | -0.652 | -0.797 | 2.47038 | 1.28306 |
K | A | B | C | D | E | F | |
S1 | 3.478 | 5.49E-04 | -2.51E-04 | 8.55E-06 | 1.35E-07 | -1.49E-08 | 2.24E-10 |
S2 | -0.496 | 1.03E-03 | 3.61E-04 | -1.93E-04 | 9.39E-06 | 1.16E-06 | -1.16E-07 |
S4 | -9.426 | 9.64E-03 | -1.53E-03 | 2.55E-04 | -3.29E-05 | 2.62E-06 | -9.88E-08 |
S5 | -2.802 | 4.08E-03 | -4.08E-04 | -2.25E-05 | 1.39E-05 | -1.70E-06 | 6.38E-08 |
S8 | -2.54 | 1.58E-02 | -2.68E-03 | 1.97E-04 | 8.87E-06 | -2.54E-06 | 1.26E-07 |
S9 | -9.267 | 0.0205 | -2.14E-03 | 9.52E-05 | 5.41E-06 | -7.59E-07 | 2.26E-08 |
All the other are not stated part and see the first application examples, repeat no more.
3rd application examples
See Figure 14-Figure 19, should in use-case, the f=5.78mm of day and night monitoring camera, F#=2.3, FOV=65 °, focal length and the mutual relationship thereof of each eyeglass are as shown in the table:
f1 | f2 | f3 | f4 | f1/f2 | f3/f4 | f2/f3 | f1/f4 |
-7.69 | 8.289 | 5.0775 | -5.34 | -0.928 | -0.951 | 1.6325 | 1.44007 |
K | A | B | C | D | E | F | |
S1 | 0 | -1.32E-03 | -2.49E-05 | 9.03E-06 | 9.81E-08 | -2.92E-08 | -6.13E-10 |
S2 | -0.0801 | -8.16E-04 | 1.15E-04 | -7.28E-05 | 1.46E-05 | 6.43E-08 | -1.10E-07 |
S4 | -10.963 | 9.60E-03 | -1.48E-03 | 2.41E-04 | -3.41E-05 | 2.79E-06 | -8.80E-08 |
S5 | -3.7881 | 6.08E-03 | -3.26E-04 | -4.40E-05 | 1.07E-05 | -1.53E-06 | 2.06E-07 |
S8 | -3.2516 | 1.69E-02 | -2.65E-03 | 2.02E-04 | 8.15E-06 | -2.65E-06 | 2.55E-07 |
S9 | -19.7638 | 0.0219 | -1.96E-03 | 1.03E-04 | 4.00E-06 | -7.30E-07 | 5.94E-08 |
All the other are not stated part and see the first application examples, repeat no more.
More than show and describe ultimate principle of the present utility model and principal character and advantage of the present utility model.The technician of the industry should understand; the utility model is not restricted to the described embodiments; what describe in above-described embodiment and instructions just illustrates principle of the present utility model; under the prerequisite not departing from the utility model spirit and scope; the utility model also has various changes and modifications, and these changes and improvements all fall within the scope of claimed the utility model.The claimed scope of the utility model is defined by appending claims and equivalent thereof.
Claims (6)
1. a day and night monitoring camera, be disposed with the first lens (L1), the second lens (L2), the 3rd lens (L3) and the 4th lens (L4) from the object side to the image side, it is characterized in that described first lens (L1) are negative focal length aspherical lens, second lens (L2) are positive focal length biconvex spheric glass, 3rd lens (L3) are positive focal length biconvex aspherical lens, and the 4th lens (L4) are negative focal length aspherical lens; Wherein, the focal length of described first lens (L1) is f1, and the focal length of the 4th lens (L4) is f4, has 1.227<f1/f4<1.44.
2. day and night monitoring camera according to claim 1, it is characterized in that described first lens (L1) are for negative focal length plastic cement aspherical lens, second lens (L2) are positive focal length biconvex glass spheric glass, 3rd lens (L3) are positive focal length biconvex plastic cement aspherical lens, and the 4th lens (L4) are negative focal length plastic cement aspherical lens.
3. day and night monitoring camera according to claim 1, the focal length that it is characterized in that described second lens (L2) is f2, the focal length of the 3rd lens (L3) is f3, has 1.632<f2/f3<2.603.
4. day and night monitoring camera according to claim 1, the focal length that it is characterized in that described first lens (L1) is f1, the focal length of the second lens (L2) is f2, has-0.928<f1/f2<-0.627.
5. day and night monitoring camera according to claim 1, the focal length that it is characterized in that described 3rd lens (L3) is f3, the focal length of the 4th lens (L4) is f4, has-0.951<f3/f4<-0.752.
6., according to the arbitrary described day and night monitoring camera of claim 1 to 5, it is characterized in that being provided with diaphragm (10) between described first lens (L1) and the second lens (L2).
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105403984A (en) * | 2015-11-23 | 2016-03-16 | 舜宇光学(中山)有限公司 | Day-and-night monitoring lens device |
CN106646826A (en) * | 2016-12-12 | 2017-05-10 | 雅安格纳斯光电科技有限公司 | Day-night confocal glass and plastic hybrid lens |
TWI588531B (en) * | 2016-07-21 | 2017-06-21 | Tan Cian Technology Co Ltd | Wide angle imaging lens group |
US11237362B2 (en) | 2019-01-31 | 2022-02-01 | Largan Precision Co., Ltd. | Electronic device |
CN114721134A (en) * | 2022-05-10 | 2022-07-08 | 鸿日光学科技(福建)有限责任公司 | Glass-plastic hybrid security monitoring lens and control method thereof |
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2015
- 2015-11-23 CN CN201520943446.8U patent/CN205210401U/en active Active
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105403984A (en) * | 2015-11-23 | 2016-03-16 | 舜宇光学(中山)有限公司 | Day-and-night monitoring lens device |
TWI588531B (en) * | 2016-07-21 | 2017-06-21 | Tan Cian Technology Co Ltd | Wide angle imaging lens group |
CN106646826A (en) * | 2016-12-12 | 2017-05-10 | 雅安格纳斯光电科技有限公司 | Day-night confocal glass and plastic hybrid lens |
US11237362B2 (en) | 2019-01-31 | 2022-02-01 | Largan Precision Co., Ltd. | Electronic device |
CN114721134A (en) * | 2022-05-10 | 2022-07-08 | 鸿日光学科技(福建)有限责任公司 | Glass-plastic hybrid security monitoring lens and control method thereof |
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