CN201434930Y

CN201434930Y - Megapixel large aperture vehicle-mounted forward-looking camera lens

Info

Publication number: CN201434930Y
Application number: CN 200920122166
Authority: CN
Inventors: 裘文伟
Original assignee: Ningbo Sunny Opotech Co Ltd
Current assignee: Ningbo Sunny Opotech Co Ltd
Priority date: 2009-06-09
Filing date: 2009-06-09
Publication date: 2010-03-31
Anticipated expiration: 2019-06-09

Abstract

The utility model relates to a megapixel large aperture vehicle-mounted forward-looking camera lens, comprising a front lens group with negative power, an aperture slot and a rear lens group with positive power, which are sequentially arranged from an object space; the front lens group is composed of a first lens with negative power and a second lens positive power, and the rear lens group is composed of a third lens, a fifth lens and a sixth lens, which are provided with the positive power, and a fourth lens with the negative power; The camera lens can realize large relative aperture, high imaging definition and small lens outer diameter, is beneficial to controlling the total length of a whole optical system, can effectively correct various optical aberrations and achieve the requirements of high definition with more than megapixel, and is particularly suitable for day and night monitoring or the monitoring under severe conditions and vehicle-mounted camera systems.

Description

Megapixels large aperture vehicle front view lens

Technical field

The utility model relates to a kind of vehicle-mounted front view lens system, is particularly suitable for taking into account day and night or the monitoring that lighting condition is relatively poor and the Megapixels large aperture vehicle front view lens of in-vehicle camera system.

Background technology

Auto industry is developed to active safety gradually by passive security (as air bag) at present, vehicle-mounted front view lens is because the specific (special) requirements of installing and using, the front end bore of requirement camera lens can not be greater than rear end (depending on nearly image aspect puts), require the logical luminous energy power of camera lens strong, can adapt to the extraneous complex environment brightness conditions that changes, require camera lens that higher sharpness is arranged, can effectively discern the identification information in road trajectory and roadside, to satisfy the specific (special) requirements of active safety function, therefore, develop and a kind ofly adaptively have the vehicle-mounted forward sight of active safety function or a kind of high-performance optics camera lens of side-looking camera is the task of top priority.

Summary of the invention

Technical problem to be solved in the utility model is to overcome above-mentioned technical deficiency and a kind of large aperture, high-resolution, the satisfactory high performance vehicle-mounted front view lens of physical dimension is provided, with reach the logical luminous energy power of camera lens strong, can adapt to external world's variation complex environment brightness conditions, effectively discern the identification information in road trajectory and roadside.

Technical matters of the present utility model solves by following technical proposals:

A kind of Megapixels large aperture vehicle front view lens begins to be provided with successively front lens group, diaphragm and rear lens group from object space, it is characterized in that:

Described front lens group has negative focal power, and rear lens group has positive focal power;

Described its first lens of front lens group with negative focal power are the eyeglass with negative power of concave-concave, and second lens are the eyeglass with positive light coke of biconvex;

Described rear lens group with positive focal power is made up of four lens units, wherein the 3rd lens and the 6th lens are the eyeglass with positive light coke of biconvex, the 4th lens are the eyeglass with negative power of concave-concave, and the 5th lens are to have the positive bent moon eyeglass of the concave surface of positive light coke towards object space.

Described front lens group satisfies the following conditions formula:

-5 〉=F _Before/ F 〉=-78

F wherein _BeforeThe combined focal length value of expression front lens group, F represents whole group of focal length value of the optical system of described camera lens.

Described rear lens group satisfies the following conditions formula:

3.0 〉=F _After/ F 〉=1.0

F wherein _AfterThe combined focal length value of expression rear lens group, F represents whole group of focal length value of the optical system of described camera lens.

Described first lens element satisfies the following conditions formula:

Nd≤1.65，Vd≥55

Wherein Nd represents the d optical index of the first lens element material, and Vd represents the d light Abbe constant of the first lens element material.

Described first lens element satisfies the following conditions formula:

-0.9≥F ₁/F≥-3.6

Wherein F1 represents the focal length value of first lens unit, and F represents whole group of focal length value of the optical system of described camera lens.

Described optical lens f-number will satisfy following formula: FNO≤1.8.

The optical length of described optical lens satisfies following condition:

5.0≥TTL/F≥2.5

Wherein, TTL represents the distance of the first lens object space side outermost point of described optical lens to the imaging focal plane, and F represents whole group of focal length value of the optical system of described camera lens.

The total field angle of described optical lens will satisfy following formula: 80 ° 〉=2 ω 〉=40 °.

Described first～the 6th lens all adopt glass material, and the material of second～the 6th lens is the glass material of high refraction.

Compared with prior art, the utility model lens configuration can realize object lens of large relative aperture, high imaging definition and less eyeglass external diameter, on material selection, all adopt glass material, except that first lens, the glass material of the height refraction that all the other five lens use, help controlling the length overall TTL of whole optical system like this, the various aberrations of effective correcting optical system, reach the above high definition requirement of mega pixel, be specially adapted to require to take into account day and night or monitoring and in-vehicle camera system that lighting condition is relatively poor.

Description of drawings

Fig. 1 is a structural representation of the present utility model.(object space is in left-most position, is in right-most position as the side)

Fig. 2 is chromatic curve figure of the present utility model.

Fig. 3 is an astigmatism curve map of the present utility model

Fig. 4 is distortion curve figure of the present utility model.

Fig. 5 is a MTF curve map of the present utility model.

Embodiment

Below with reference to accompanying drawing embodiment of the present utility model is described in detail again.

Megapixels large aperture vehicle front view lens, as shown in Figure 1, this optical lens begins to be provided with successively front lens group, diaphragm r5, rear lens group, color filter GF, imaging surface IMA from object space.

Described front lens group has negative focal power, is made up of the first lens L1 of the concave-concave eyeglass with negative power and the second eyeglass L2 with biconvex eyeglass of positive light coke.

Described rear lens group has positive focal power, is made up of four lens units, and focal power puts in order to positive and negative, just, just, and promptly prismatic glasses L3 and the 6th lens L6 are the eyeglass with positive light coke of biconvex; The 4th eyeglass L4 is the concave-concave eyeglass with negative power, and the 5th eyeglass L5 has the positive bent moon eyeglass of positive light coke concave surface towards object space.

In addition, the formula-5 〉=F that satisfies condition of described forward and backward lens group _Before/ F 〉=-78,3.0 〉=F _After/ F 〉=1.0.The focal power allocation proportion of the forward and backward lens of so reasonable control group, one side helps controlling the incident ray height of front lens group, can not be greater than the requirement of rear end with the front end bore that meets camera lens; Can reduce chief ray shooting angle on the other hand, to improve the relative brightness of optical system through rear lens group.

The material of first lens element formula Nd≤1.65 that satisfy condition, Vd 〉=55, divergence of beam is excessive behind the light process biconcave lens that lower refractive index can be avoided being come by object space, and the light that less material dispersion performance can effectively reduce three primary colors R, G, B separates, and promptly produces aberration.

The focal length of the first lens element formula-0.9 〉=F that satisfies condition ₁/ F 〉=-3.6 make the outside dimension of first lens and aberration distribution obtain a balance preferably.

The diaphragm of camera lens is between described front lens group and rear lens group, because of having only 2 eyeglasses, front lens group forms, then lens group is made up of 4 eyeglasses, make the stop position of total system relatively near the object space end like this, can effectively control the external diameter size of front lens group on the one hand; Can reduce the FNO value (promptly improving relative aperture) of system on the other hand, to reach the large aperture requirement of FNO≤1.8.

Six lens of described camera lens all adopt glass material, and except that the material of first lens, the glass material of the height refraction that all the other five lens all use, help controlling the length overall TTL of whole optical system like this, simultaneously, the effective various aberrations of correcting optical system are to reach the high definition requirement more than the mega pixel.

Fig. 2 to Fig. 5 is the optical performance curve figure corresponding to case study on implementation, and wherein Fig. 2 is chromatic curve figure (also can be the spherical aberration curve map), represents that by F, d commonly used, the wavelength of C three coloured light unit is mm.Fig. 3 is the astigmatism curve map, represents that by F, d commonly used, the wavelength of C three coloured light unit is mm.Fig. 4 is distortion curve figure, represents the distortion sizes values under the different field angle situations, and unit is %.Fig. 5 is the MTF curve map, has represented the picture level of comprehensively separating of an optical system.

In the implementation case, the whole focal length value of this optical lens is F, f-number is FNO, field angle is 2 ω=60 °, camera lens length overall TTL=18.7mm, and begin by the object space side, with each minute surface number consecutively, the minute surface of the first eyeglass L1 is r1, r2, and the minute surface of the second eyeglass L2 is r3, r4, the diaphragm face is r5, the minute surface of prismatic glasses L3 is r6, r7, and the minute surface of the 4th eyeglass L4 is r8, r9, and the minute surface of the 5th eyeglass L5 is r10, r11, the minute surface of the 6th eyeglass L6 is r12, r13, and the minute surface of color filter GF is r14, r15.

F＝4.45mm，FNO＝1.5，2ω＝60°，TTL＝18.7mm

The optical parametric such as the table 1 of present embodiment:

Table 1

The face sequence number	Radius-of-curvature r	Center thickness d	Refractive index Nd	Abbe constant Vd
The face sequence number	Radius-of-curvature r	Center thickness d	Refractive index Nd	Abbe constant Vd	1	12.06	0.7	1.51680	64.16
2	3.83	0.9			1	12.06	0.7	1.51680	64.16
2	3.83	0.9			3	30.7	5.07	1.80400	46.57
4	-9	0.1			3	30.7	5.07	1.80400	46.57
4	-9	0.1			5	infinity	0.07
6	5.96	2.38	1.72916	54.68	5	infinity	0.07
6	5.96	2.38	1.72916	54.68	7	-9.3	0.75
8	6.28	0.7	1.84666	23.82	7	-9.3	0.75
8	6.28	0.7	1.84666	23.82	9	-6.28	0.67
10	-17.16	1.32	1.80400	46.57	9	-6.28	0.67
10	-17.16	1.32	1.80400	46.57	11	-5.56	0.1
12	8.7	1.48	1.72916	54.68	11	-5.56	0.1
12	8.7	1.48	1.72916	54.68	13	-29.38	0.6
14	infinity	0.55	1.51680	64.16	13	-29.38	0.6
14	infinity	0.55	1.51680	64.16	15	infinity
IMA	infinity				15	infinity

Claims

1, a kind of Megapixels large aperture vehicle front view lens begins to be provided with successively front lens group, diaphragm and rear lens group from object space, it is characterized in that:

2, Megapixels large aperture vehicle front view lens as claimed in claim 1 is characterized in that described front lens group satisfies the following conditions formula:

-5 〉=F _Before/ F 〉=-78

3, Megapixels large aperture vehicle front view lens as claimed in claim 1 is characterized in that described rear lens group satisfies the following conditions formula:

3.0 〉=F _After/ F 〉=1.0

4, Megapixels large aperture vehicle front view lens as claimed in claim 1 is characterized in that described first lens element satisfies the following conditions formula:

Nd≤1.65，Vd≥55

5, Megapixels large aperture vehicle front view lens as claimed in claim 1 is characterized in that described first lens element satisfies the following conditions formula:

-0.9≥F ₁/F≥-3.6

6, Megapixels large aperture vehicle front view lens as claimed in claim 1 is characterized in that described optical lens f-number will satisfy following formula: FNO≤1.8.

7, Megapixels large aperture vehicle front view lens as claimed in claim 1 is characterized in that the optical length of described optical lens satisfies following condition:

5.0≥TTL/F≥2.5

8, Megapixels large aperture vehicle front view lens as claimed in claim 1 is characterized in that the total field angle of described optical lens will satisfy following formula: 80 ° 〉=2 ω 〉=40 °.

9,, it is characterized in that described first～the 6th lens all adopt glass material, and the material of second～the 6th lens is the glass material of high refraction as each described Megapixels large aperture vehicle front view lens of claim 1～8.