CN206532026U

CN206532026U - Small low-cost 4MP is without thermalization tight shot

Info

Publication number: CN206532026U
Application number: CN201720092961.9U
Authority: CN
Inventors: 柳振全
Original assignee: Dongguan Yutong Optical Technology Co Ltd
Current assignee: Dongguan Yutong Optical Technology Co Ltd
Priority date: 2017-01-22
Filing date: 2017-01-22
Publication date: 2017-09-29
Anticipated expiration: 2027-01-22
Also published as: TWM565800U

Abstract

The utility model belongs to field of optical device technology, more particularly to a kind of small low-cost 4MP is without thermalization tight shot, including the first lens being arranged in order from the object side to the image side, second lens, 3rd lens, 4th lens and the 5th lens, first lens are concave-concave negative power plastic aspheric lens, second lens are concavo-convex positive light coke plastic aspheric lens, 3rd lens are biconvex positive light coke glass spherical lens, 4th lens are concave-concave negative power plastic aspheric lens, 5th lens are biconvex positive light coke plastic aspheric lens.Relative to prior art, the utility model adds the optical texture that the glass modeling of 4 plastic aspherical element eyeglasses is combined using 1 glass spheric glass, give full play to the advantage that glass lens are easy to process, glass lens cost is low, collocation 4MP, 1/2.7 inch of chip, visible ray can be made with reaching 4MP resolution ratio under infrared light, cost had both been reduced and in turn ensure that performance.

Description

Small low-cost 4MP is without thermalization tight shot

Technical field

The utility model belongs to field of optical device technology, more particularly to a kind of small low-cost 4MP focuses mirror without thermalization Head.

Background technology

With the development of data transfer and storing technology, in monitoring field, the monitoring for possessing high definition or full HD pixel is taken the photograph As head gradually occuping market, high-definition camera chip has 1280*720 pixel i.e. 720p, and full HD camera chip has 1920* 1080 pixel is 1080p, also in the presence of some 4MP pixel requests；Meanwhile, the size of chip differs, and main flow size is 1/3 Inch or 1/2.7 inch.The specification of chip determines the design requirement of camera lens, and 4MP, 1/2.7 inch of chip can be realized enough More preferably as matter, but at present such camera lens also exist as matter it is bad the problem of, resolution ratio has much room for improvement, and carries high-resolution side Method includes increase number of lenses, or reduces clear aperature using less eyeglass, but can cause increase or the thang-kng of cost The deficiency of amount, therefore there is the problem of performance is difficult to balance with cost.

In view of this, it is necessory to provide a kind of small low-cost 4MP without thermalization tight shot, it uses 1G+4P (a piece of + 4 glass lens of glass lens) glass modeling combine optical texture, collocation 4MP, 1/2.7 inch of chip, can make visible ray with 4MP resolution ratio is reached under infrared light, cost had both been reduced and in turn ensure that performance.

Utility model content

The purpose of this utility model is：In view of the shortcomings of the prior art, a kind of small low-cost 4MP is provided without thermalization Tight shot, it uses the optical texture that the modeling of 1G+4P (a piece of+4 glass lens of glass lens) glass is combined, collocation 4MP, 1/ 2.7 inches of chip, can make visible ray with reaching 4MP resolution ratio under infrared light, both reduce cost and in turn ensure that performance.

In order to achieve the above object, the utility model is adopted the following technical scheme that：

Small low-cost 4MP is without thermalization tight shot, including the first lens, second saturating being arranged in order from the object side to the image side Mirror, the 3rd lens, the 4th lens and the 5th lens, first lens are concave-concave negative power plastic aspheric lens, described Second lens are concavo-convex positive light coke plastic aspheric lens, and the 3rd lens are biconvex positive light coke glass spherical lens, 4th lens are concave-concave negative power plastic aspheric lens, and the 5th lens are biconvex positive light coke plastic aspherical element Lens；

The ratio of the focal length of 3rd lens and the 5th lens and the focal length of whole camera lens meets following article Part：

1.94 ＜ | f3/f | ＜ 2.35；

0.97 ＜ | f5/f | ＜ 1.53；

Wherein, f is the focal length of whole camera lens；F3 is the focal length of the 3rd lens；F5 is the focal length of the 5th lens.

It is used as a kind of improvement of the utility model small low-cost 4MP without thermalization tight shot, first lens to institute Focal length, refractive index and the radius of curvature for stating the 5th lens meet following condition：

In upper table, " f " is focal length, and " n " is refractive index, and " R " is radius of curvature, and "-" number represents that direction is negative；

Wherein, f1 to f5 corresponds respectively to first lens to the focal length of the 5th lens；N1 to n5 is corresponded to respectively In the refractive index of first lens to the 5th lens；R1, R3, R5, R7 and R9 correspond respectively to first lens extremely The radius of curvature of the one side of the close object space of 5th lens, R2, R4, R6, R8 and R10 correspond respectively to first lens To the radius of curvature of the one side of the remote object space of the 5th lens.

Improved as a kind of without thermalization tight shot of the utility model small low-cost 4MP, it is first lens, described Second lens, the 4th lens and the 5th lens meet equation below：

Wherein：Z is the non-spherical lens along optical axis direction at the position that height is y, away from the non-spherical lens top Point apart from rise, c=1/R, R represents the radius of curvature at the non-spherical lens Mian Xing centers, and k represents circular cone coefficient, parameter A, B, C, D, E, F are high order aspheric surface coefficient.

As a kind of improvement of the utility model small low-cost 4MP without thermalization tight shot, first lens and institute The second lens are stated by soma close-fittings, soma is anti-dazzling screen.

As a kind of improvement of the utility model small low-cost 4MP without thermalization tight shot, second lens and institute State the 3rd lens and pass through spacer ring close-fitting.

As a kind of improvement of the utility model small low-cost 4MP without thermalization tight shot, the 3rd lens and institute State the 4th lens and pass through spacer ring close-fitting.

As a kind of improvement of the utility model small low-cost 4MP without thermalization tight shot, the 4th lens and institute State the 5th lens and pass through soma close-fittings.

Relative to prior art, the utility model has the following advantages：

First, the first lens of the present utility model, the second lens, the 4th lens and the 5th lens employ glass lens, Accomplish low cost and high-performance, the cost of glass lens is far below glass spheric glass, so reduce cost；Again due to this The first lens, the second lens, the 4th lens and the 5th lens of utility model employ aspherical lens, compared to traditional ball Face eyeglass improves performance.

Second, the utility model adds the optics that the glass modeling of 4 plastic aspherical element eyeglasses is combined using 1 glass spheric glass Structure, gives full play to the advantage that glass lens are easy to process, glass lens cost is low, collocation 4MP, 1/2.7 inch of chip, energy Make visible ray with reaching 4MP resolution ratio under infrared light, both reduced cost and in turn ensure that performance.

3rd, visible ray of the present utility model can reach million grades of pixels, pass through reasonable employment glass and optical plastic group Close, image quality is good, and cause visual light imaging clearly in the case of without focusing can to infrared light also blur-free imaging, And cause infrared imaging also to reach mega pixel, clearly bright monitoring picture can be also realized under night low-light (level) Face, realizes day and night confocal function.It is provided simultaneously with temperature compensation function and passive without thermalization function, can reaches at -30~+80 DEG C Used under environment and do not run Jiao.

Brief description of the drawings

Fig. 1 is optical texture schematic diagram of the present utility model.

Fig. 2 is assembling assumption diagram of the present utility model.

Embodiment

The utility model and its advantage are described in further detail below with reference to specific embodiment, still, Embodiment of the present utility model is not limited thereto.

As depicted in figs. 1 and 2, the utility model provide a kind of small low-cost 4MP without thermalization tight shot, including from The first lens 1, the second lens 2, the 3rd lens 3, the 4th lens 4 and the 5th lens 5 that object space is arranged in order to image space, first is saturating Mirror 1 is concave-concave negative power plastic aspheric lens, and the second lens 2 are concavo-convex positive light coke plastic aspheric lens, and the 3rd is saturating Mirror 3 is biconvex positive light coke glass spherical lens, and the 4th lens 4 are concave-concave negative power plastic aspheric lens, the 5th lens 5 For biconvex positive light coke plastic aspheric lens；

The ratio of the focal length of 3rd lens 3 and the 5th lens 5 and the focal length of whole camera lens meets following condition：

1.94 ＜ | f3/f | ＜ 2.35；

0.97 ＜ | f5/f | ＜ 1.53；

Wherein, f is the focal length of whole camera lens；F3 is the focal length of the 3rd lens 3；F5 is the focal length of the 5th lens 5, to reach Miniaturization, high performance purpose.

Focal length, refractive index and the radius of curvature of the lens 5 of first lens 1 to the 5th meet following condition：

Wherein, f1 to f5 corresponds respectively to the focal length of the lens 5 of the first lens 1 to the 5th；N1 to n5 corresponds respectively to first The refractive index of the lens 5 of lens 1 to the 5th；R1, R3, R5, R7 and R9 correspond respectively to the close of the lens 5 of the first lens 1 to the 5th The radius of curvature of the one side of object space, R2, R4, R6, R8 and R10 correspond respectively to the remote object space of the lens 5 of the first lens 1 to the 5th One side radius of curvature.

First lens 1, the second lens 2, the 4th lens 4 and the 5th lens 5 meet equation below：

Wherein：Z is non-spherical lens along optical axis direction at the position that height is y, the distance away from non-spherical lens summit Rise, c=1/R, R represents the radius of curvature at non-spherical lens Mian Xing centers, and k represents circular cone coefficient, and parameter A, B, C, D, E, F are High order aspheric surface coefficient.

First lens 1 and the second lens 2 pass through soma close-fittings.

Second lens 2 and the 3rd lens 3 pass through spacer ring close-fitting.

3rd lens 3 and the 4th lens 4 pass through spacer ring close-fitting.

4th lens 4 and the 5th lens 5 pass through soma close-fittings.

Embodiment 1

As illustrated in fig. 1 and 2, a kind of small low-cost 4MP is present embodiments provided without thermalization tight shot, including from object space The first lens 1, the second lens 2, the 3rd lens 3, the 4th lens 4 and the 5th lens 5 being arranged in order to image space, the first lens 1 For concave-concave negative power plastic aspheric lens, the second lens 2 are concavo-convex positive light coke plastic aspheric lens, the 3rd lens 3 For biconvex positive light coke glass spherical lens, the 4th lens 4 are concave-concave negative power plastic aspheric lens, and the 5th lens 5 are Biconvex positive light coke plastic aspheric lens；First lens 1 and the second lens 2 pass through soma close-fittings.Second lens 2 and the 3rd saturating Mirror 3 passes through spacer ring close-fitting.3rd lens 3 and the 4th lens 4 pass through spacer ring close-fitting.4th lens 4 and the 5th lens 5 pass through soma Close-fitting.

In the present embodiment, face type, radius of curvature R, lens thickness, eyeglass spacing, lens index nd and the K value of each lens Following condition (table 1) is met respectively：

In table 1, " R " is radius of curvature, and "-" number represents that direction is negative, and " PL " represents plane, and upper table the same face sequence number is existing Refractive index data nd, has data D, data D to represent the thickness at the lens axial line again, the same face sequence number there was only data D and There is no refractive index data nd, data D to represent the lens to the spacing of next lens face.It is saturating that face sequence number 1 and 2 corresponds to first respectively The face towards the face of object space and towards image space of mirror 1；Face sequence number 3 and 4 correspond to respectively the second lens 2 towards the face of object space and court To the face of image space；Face sequence number 5 and 6 corresponds to the face towards the face of object space and towards image space of the 3rd lens 3 respectively；Face sequence number 7 and 8 The face towards the face of object space and towards image space of the 4th lens 4 is corresponded to respectively；Face sequence number 9 and 10 corresponds to the 5th lens 5 respectively Face towards the face of object space and towards image space.

The face of face serial number 1,2,3,4,7,8,9 and 10 is aspherical in table 1, and aspherical lens meet equation below：

Aspherical face shape parameter is shown in Table 2 in the present embodiment：

Table 2：The aspherical parameter on the surface of the 1st, 2,3,4,7,8,9 and 10.

In a word, the utility model has the following advantages：

First, the first lens 1 of the present utility model, the second lens 2, the 4th lens 4 and the 5th lens 5 employ plastic lens Piece, has accomplished low cost and high-performance, the cost of glass lens is far below glass spheric glass, so reduce cost；And by Aspherical lens are employed in the first lens 1 of the present utility model, the second lens 2, the 4th lens 4 and the 5th lens 5, are compared Traditional spheric glass improves performance.

The announcement and teaching of book according to the above description, the utility model those skilled in the art can also be to above-mentioned reality The mode of applying carries out appropriate change and modification.Therefore, the utility model is not limited to specific implementation disclosed and described above Some modifications and changes of the present utility model should also be as falling into scope of the claims of the present utility model by mode. Although in addition, used some specific terms in this specification, these terms merely for convenience of description, not to this reality With any limitation of new composition.

Claims

1. small low-cost 4MP is without thermalization tight shot, it is characterised in that：First including being arranged in order from the object side to the image side is saturating Mirror, the second lens, the 3rd lens, the 4th lens and the 5th lens, first lens are concave-concave negative power plastic aspherical element Lens, second lens are concavo-convex positive light coke plastic aspheric lens, and the 3rd lens are biconvex positive light coke glass Spherical lens, the 4th lens are concave-concave negative power plastic aspheric lens, and the 5th lens are biconvex positive light coke Plastic aspheric lens；

The ratio of the focal length of 3rd lens and the 5th lens and the focal length of whole camera lens meets following condition：

1.94 ＜ | f3/f | ＜ 2.35；

0.97 ＜ | f5/f | ＜ 1.53；

2. small low-cost 4MP according to claim 1 is without thermalization tight shot, it is characterised in that：First lens Focal length, refractive index and radius of curvature to the 5th lens meet following condition：

Wherein, f1 to f5 corresponds respectively to first lens to the focal length of the 5th lens；N1 to n5 corresponds respectively to institute The first lens are stated to the refractive index of the 5th lens；R1, R3, R5, R7 and R9 correspond respectively to first lens to described The radius of curvature of the one side of the close object space of 5th lens, R2, R4, R6, R8 and R10 correspond respectively to first lens to institute State the radius of curvature of the one side of the remote object space of the 5th lens.

3. small low-cost 4MP according to claim 1 is without thermalization tight shot, it is characterised in that：First lens, Second lens, the 4th lens and the 5th lens meet equation below：

Wherein：Z is the non-spherical lens along optical axis direction at the position that height is y, away from the non-spherical lens summit Apart from rise, c=1/R, R represents the radius of curvature at the non-spherical lens Mian Xing centers, and k represents circular cone coefficient, parameter A, B, C, D, E, F are high order aspheric surface coefficient.

4. small low-cost 4MP according to claim 1 is without thermalization tight shot, it is characterised in that：First lens Pass through anti-dazzling screen close-fitting with second lens.

5. small low-cost 4MP according to claim 1 is without thermalization tight shot, it is characterised in that：Second lens Pass through spacer ring close-fitting with the 3rd lens.

6. small low-cost 4MP according to claim 1 is without thermalization tight shot, it is characterised in that：3rd lens Pass through spacer ring close-fitting with the 4th lens.

7. small low-cost 4MP according to claim 1 is without thermalization tight shot, it is characterised in that：4th lens Pass through anti-dazzling screen close-fitting with the 5th lens.