CN105137567A - Imaging lens, imaging module and iris recognition device - Google Patents

Abstract

The invention discloses an imaging lens, an imaging module and an iris recognition device. The imaging lens, the imaging module and the iris recognition device belong to the field of biological recognition. The imaging lens comprises the following components in a light incident direction: a first lens which is a biconvex lens with a positive focal power, wherein the front surface and the back surface of the first lens are convex surfaces; a second lens which is a convexoconcavelens with a positive focal power, wherein the front surface of the second lens is a convex surface and the back surface of the second lens is a recessed surface; a third lens which is a convexoconcave lens with a negative focal power, wherein the front surface of the third lens is a convex surface and the back surface of the third lens is a recessed surface; a fourth lens which is a convexoconcave lens with a positive focal power, wherein the front surface of the fourth lens is a convex surface and the back surface of the fourth lens is a recessed surface; and a fifth lens which is a biconvex lens with a positive focal power, wherein the front surface and the back surface of the fifth lens are convex surfaces. The fourth lens is connected with the fifth lens through an adhesive. The imaging lens has advantages of high imaging quality, wide acquisition range, convenient use, simple structure, convenient assembling and low fabrication cost.

Description

Imaging lens, iris imaging module and iris identification device

Technical field

The present invention relates to field of biological recognition, refer to a kind of imaging lens, iris imaging module and iris identification device especially.

Background technology

Iris recognition is the biological identification technology that a kind of iris texture information based on being less than 10mm region carries out processing authenticated identity, the realizing difficult point and be how to collect clear high-quality iris image and high-quality iris image acquiring optical system of this technology.Current existing iris capturing optical system can be divided into: varifocal optical system and focus optical system, and wherein varifocal optical system volume is large, complex structure, cost are high, and assembly difficulty is large; Focus optical system structure simple, cost is low, and device is convenient, and product on the market generally adopts and focuses optical system at present, but the existing optical system that focuses mostly is monocular collection optical system, the imageing sensor (VGA) of its lower pixel of generally arranging in pairs or groups.

But gather eyes, require high to the fitness of user, and equipment can acquisition range (depth of field) very narrow, extremely inconvenient in use, be unfavorable for holding distance and aiming at.

Summary of the invention

The invention provides a kind of imaging lens, iris imaging module and iris identification device, this lens imaging quality is good, and acquisition range is wide, easy to use, and structure is simple, and easy to assembly, cost is low.

For solving the problems of the technologies described above, the invention provides technical scheme as follows:

A kind of imaging lens, comprises from front to back successively along light direction:

First lens, described first lens are the biconvex lens with positive light coke, and its front surface is convex surface, and rear surface is convex surface;

Second lens, described second lens are the meniscus with positive light coke, and its front surface is convex surface, and rear surface is concave surface;

3rd lens, described 3rd lens are the meniscus with negative power, and its front surface is convex surface, and rear surface is concave surface;

4th lens, described 4th lens are the meniscus with positive light coke, and its front surface is convex surface, and rear surface is concave surface;

5th lens, described 5th lens are the biconvex lens with positive light coke, and its front surface is convex surface, and rear surface is convex surface;

Described 4th lens and the 5th lens glue are combined.

A kind of iris imaging module, comprise above-mentioned arbitrary imaging lens and be positioned at the imageing sensor at described imaging lens rear, described imageing sensor is CCD or cmos sensor.

A kind of iris identification device, the hardware circuit comprising above-mentioned iris imaging module and be connected with described iris imaging module.

The present invention has following beneficial effect:

Compared with prior art, along light direction, vertical five lens are followed successively by biconvex lens, meniscus, meniscus, meniscus and biconvex lens to imaging lens of the present invention, and wherein the 4th lens and the 5th lens glue are combined.This imaging lens has higher image quality at near-infrared band, distorts little; Field depth is wide, and object distance range is large, makes acquisition range wide; The present invention is particularly useful for binocular iris capturing, requires low, easy to use to the fitness of user; Five lens are spherical lens, do not have non-spherical lens, and structure is simple, and easy to assembly, cost is low.

Accompanying drawing explanation

Fig. 1 is the structural representation of imaging lens of the present invention;

Fig. 2 is the structural representation of imaging lens embodiment one of the present invention;

The optical performance curve figure that Fig. 3 is imaging lens shown in Fig. 2, wherein: 3A is the distortion curve figure of embodiment one; 3B is the curvature of field curve map of embodiment one; 3C is the MTF performance diagram one of embodiment one; 3D is the MTF performance diagram two of embodiment one; 3E is the MTF performance diagram three of embodiment one;

Fig. 4 is the structural representation of imaging lens embodiment two of the present invention;

The optical performance curve figure that Fig. 5 is imaging lens shown in Fig. 4, wherein: 5A is the distortion curve figure of embodiment two; 5B is the curvature of field curve map of embodiment two; 5C is the MTF performance diagram one of embodiment two; 5D is the MTF performance diagram two of embodiment two; 5E is the MTF performance diagram three of embodiment two.

Embodiment

For making the technical problem to be solved in the present invention, technical scheme and advantage clearly, be described in detail below in conjunction with the accompanying drawings and the specific embodiments.

On the one hand, the invention provides a kind of imaging lens, as shown in Figure 1, comprise successively from front to back along light direction:

First lens 1, first lens 1 are for having the biconvex lens of positive light coke, and its front surface 11 is convex surface, and rear surface 12 is convex surface;

Second lens 2, second lens 2 are for having the meniscus of positive light coke, and its front surface 21 is convex surface, and rear surface 22 is concave surface;

3rd lens the 3, three lens 3 are for having the meniscus of negative power, and its front surface 31 is convex surface, and rear surface 32 is concave surface;

4th lens the 4, four lens 4 are for having the meniscus of positive light coke, and its front surface 41 is convex surface, and rear surface 42 is concave surface;

5th lens the 5, five lens 5 are for having the biconvex lens of positive light coke, and its front surface 51 is convex surface, and rear surface 52 is convex surface;

4th lens 4 and the 5th lens 5 glued together, in Fig. 1,42 and 51 is same, and label is 42/51.

The front surface of each lens above-mentioned refers to that the face that infrared light is injected, rear surface refer to the face that infrared light penetrates, lower same.

Compared with prior art, along light direction, vertical five lens are followed successively by biconvex lens, meniscus, meniscus, meniscus and biconvex lens to imaging lens of the present invention, and wherein the 4th lens and the 5th lens glue are combined.This imaging lens has higher image quality at near-infrared band, distorts little; Field depth is wide, and object distance range is large, makes acquisition range wide; The present invention is particularly useful for binocular iris capturing, requires low, easy to use to the fitness of user; Five lens are spherical lens, do not have non-spherical lens, and structure is simple, and easy to assembly, cost is low.

As a modification of the present invention, the focal length of each lens can meet: 1.8f≤f1≤2.3f, 0.45f≤f2≤1.1f ,-0.55f≤f3≤-0.33f, 1.05f≤f4≤1.35f, 0.9f≤f5≤1.67f; Wherein, f is total focal length of imaging lens, and f1 is first focal length of lens, and f2 is second focal length of lens, and f3 is the 3rd focal length of lens, and f4 is the 4th focal length of lens, and f5 is the 5th focal length of lens.

When the focal length of each lens meets above-mentioned relation, at near-infrared band, there is higher image quality, almost undistorted.

Further, 17mm≤f1≤21mm, 4mm≤f2≤9.5mm ,-5mm≤f3≤-3mm, 9.5mm≤f4≤12mm, 8mm≤f5≤15mm; 200mm≤h≤400mm, Δ h >=110mm; Wherein, h is object distance, and Δ h is object space field depth, Δ h=object space shooting distance farthest-object space minimum photographic distance.Now, imaging lens is applicable to the binocular iris image acquiring within the scope of 20-40cm, has larger object space field depth.

Improve as another kind of the present invention, the material of the first lens 1, second lens 2, the 3rd lens 3, the 4th lens 4 and the 5th lens 5 meets: 1.6≤nd≤1.8,25≤vd≤55, wherein, nd is the refractive index of lens material, and vd is the abbe number of lens material.Adopt the material of above-mentioned refractive index and abbe number can either obtain good image quality, can material cost be saved again.

Preferably, as shown in Figure 1, Figure 2 and Figure 4, diaphragm 6 for controlling near infrared light percent of pass (6 ', 6 ") is provided with between the 3rd lens 3 and the 4th lens 4.Diaphragm can regulate the power of the near infrared light beam passed through, and can select different diaphragms under different photoenvironments.

Improve as another kind of the present invention, can be coated with on certain surface of certain lens can reflect visible light through the filter coating (as near-infrared band narrow-band-filter film) of near infrared light, be preferably coated with filter coating at the front surface of the first lens; Filter coating can avoid visible ray to the interference of imaging lens, and meanwhile, the visible ray of reflection can make user from imaging lens, see the eyes image of self, facilitates user to regulate self-position, plays the effect of location.And front surface and the rear surface of the rear surface of the first lens and the second lens, the 3rd lens, the 4th lens and the 5th lens are all coated with the near-infrared band anti-reflection film that can strengthen near infrared light transmitance.Anti-reflection film can strengthen the transmitance of near infrared light, can obtain iris image more clearly with less emissive power.

Or, as shown in Figure 4, imaging lens also comprise can reflect visible light and through the optically flat filter 7 of near infrared light ", optically flat filter can be positioned at whole imaging lens foremost or rearmost end; preferably rearmost end, and optically flat filter can avoid visible ray to the interference of imaging lens; Front surface and the rear surface of the first lens, the second lens, the 3rd lens, the 4th lens and the 5th lens are all coated with the near-infrared band anti-reflection film that can strengthen near infrared light transmitance.Anti-reflection film can strengthen the transmitance of near infrared light, can obtain iris image more clearly with less emissive power.

In the present invention, the wave band of above-mentioned near infrared light is 700-900nm.The near infrared light of this wave band can collect the iris image of better quality.

For further cost-saving, the material of the first lens, the second lens, the 3rd lens, the 4th lens and the 5th lens can be glass.

With two specific embodiments, the present invention will be further elaborated below:

Embodiment one:

The present embodiment is a kind of imaging lens for binocular iris recognition, as shown in Figure 2, be made up of five lens combination and diaphragm 6 ', the rear of imaging lens is provided with imageing sensor 8 ', be followed successively by along light direction: first lens 1 ' with positive light coke, it is biconvex lens, and its front surface 11 ' is convex surface, and rear surface 12 ' is convex surface; Have the second lens 2 ' of positive light coke, it is meniscus, and its front surface 21 ' is convex surface, and rear surface 22 ' is concave surface; Have the 3rd lens 3 ' of negative power, it is meniscus, and its front surface 31 ' is convex surface, and rear surface 32 ' is concave surface; 4th lens 4 ' and the 5th lens 5 ' are gummed mirror, and the 4th lens 4 ' are for having the meniscus of positive light coke, and its front surface 41 ' is convex surface, and rear surface 42 ' is concave surface; 5th lens 5 ' are for having the biconvex lens of positive light coke, and its front surface 51 ' is convex surface, and rear surface 52 ' is convex surface; Diaphragm 6 ' is positioned between the 3rd lens 3 ' and the 4th lens 4 ', and five lens are glass material; Imaging surface is imageing sensor face, and it is CCD or cmos sensor.

The imaging lens imaging wavelength of the present embodiment is near-infrared band 700-900nm, for avoiding the interference of other light when ensureing imaging, at certain one side plating near-infrared band narrow-band-filter film of certain lens, realize the effect of filtering visible light-transmissive near infrared light, preferably at the front surface plating near-infrared band narrow-band-filter film of the first lens, filter coating can avoid visible ray to the interference of imaging lens, simultaneously, the visible ray of reflection can make user from imaging lens, see the eyes image of self, facilitate user to regulate self-position, play the effect of location.And for increasing the transmitance of near-infrared band light, every other each face is coated with near infrared anti-reflection film.

As aperture FNO.=5, (FNO. is the ratio of focal length and effective aperture to the imaging lens of the present embodiment, be used for describing the size of aperture), when optimal focusing object distance is 300mm, concrete structure parameter refers to table one, comprises the surface type of lens face, radius-of-curvature, lens thickness, refractive index, abbe number etc.The focal length of lens parameter of the present embodiment optical system is: the first focal length of lens f1=19.5mm, second focal length of lens f2=7.3mm, 3rd focal length of lens f3=-4.4mm, 4th focal length of lens f4=11.5mm the 5th focal length of lens f5=12.1mm, Δ h=110mm, clear binocular iris image can be gathered, for the binocular iris image acquiring of relative broad range within the scope of 250-360mm.

Table one: the embodiment one concrete structure parameter of imaging lens of the present invention

Fig. 3 is the distortion curve figure (%) that the optical performance curve figure of the present embodiment imaging lens, 3A show the present embodiment, and within the scope of full filed, distortion aberration is all in 0.5% scope; 3B shows the curvature of field curve map (mm) of the present embodiment, and within the scope of full filed, the curvature of field aberration of meridian ellipse and each light of sagittal surface is all less than 0.05mm; 3C shows the MTF (ModulationTransferFunction of the embodiment of the present invention, modulation transfer function) family curve, find out when object distance 300mm from curve, the MTF of each visual field all close to diffraction limit, at spatial frequency 100lp/mm place mtf value more than 0.4; 3D shows the MTF curve of the embodiment of the present invention when object distance 250mm, as seen from the figure now at spatial frequency 100lp/mm place mtf value about 0.3; 3E shows the MTF curve of the embodiment of the present invention when object distance 360mm, as seen from the figure now at spatial frequency 100lp/mm place mtf value about 0.3; As can be seen from above optical indicatrix figure, the imaging lens distortion of the present embodiment is little, have higher image quality, and field depth is wide.

Embodiment two:

The present embodiment is a kind of imaging lens for binocular iris recognition, as shown in Figure 4, by five lens combination, diaphragm 6 " and optically flat filter 7 " form, the rear of imaging lens is provided with imageing sensor 8 "; be followed successively by along light direction: first lens 1 with positive light coke ", it is biconvex lens, its front surface 11 " be convex surface, rear surface 12 " be convex surface; There are the second lens 2 of positive light coke ", it is meniscus, its front surface 21 " be convex surface, rear surface 22 " be concave surface; There are the 3rd lens 3 of negative power ", it is meniscus, its front surface 31 " be convex surface, rear surface 32 " be concave surface; 4th lens 4 " and the 5th lens 5 " be gummed mirror, the 4th lens 4 " for having the meniscus of positive light coke, its front surface 41 " be convex surface, rear surface 42 " be concave surface; 5th lens 5 " for having the biconvex lens of positive light coke, its front surface 51 " be convex surface, rear surface 52 " be convex surface; Diaphragm 6 " be positioned at the 3rd lens 3 " and the 4th lens 4 " between, five lens are glass material; Imaging surface is imageing sensor face, and it is CCD or cmos sensor.

The imaging lens imaging wavelength of the present embodiment is near-infrared band 700-900nm, adopt optically flat filter 7 " filtering light disturbance; optically flat filter 7 " front surface is 71 "; rear surface is 72 ", optically flat filter 7 " material meet 1.4≤nd≤1.6; 60≤vd≤70; optically flat filter 7 " whole imaging lens can be positioned at foremost or rearmost end, namely preferred rearmost end is positioned at the 5th lens 5 " and imageing sensor 8 " between, it is near-infrared band narrow band pass filter, is 700-900nm through wavelength.The front surface of each lens and rear surface are coated with near-infrared band anti-reflection film, strengthen the transmitance of near-infrared band light.

As aperture FNO.=5.1, (FNO. is the ratio of focal length and effective aperture to the imaging lens of the present embodiment, be used for describing the size of aperture), when optimal focusing object distance is 300mm, concrete structure parameter refers to table two, comprises the surface type of lens face, radius-of-curvature, lens thickness, refractive index, abbe number etc.The focal length of lens parameter of the present embodiment optical system is: the first focal length of lens f1=18.9mm, second focal length of lens f2=6.85mm, 3rd focal length of lens f3=-4.8mm, 4th focal length of lens f4=10.9mm the 5th focal length of lens f5=13.2mm, Δ h=110mm, clear binocular iris image can be gathered, for the binocular iris image acquiring of relative broad range within the scope of 250-360mm.

Table two: the embodiment two concrete structure parameter of imaging lens of the present invention

Fig. 5 is the distortion curve figure (%) that the optical performance curve figure of the present embodiment imaging lens, 3A show the present embodiment, and within the scope of full filed, distortion aberration is all in 0.5% scope; 3B shows the curvature of field curve map (mm) of the present embodiment, and within the scope of full filed, the curvature of field aberration of meridian ellipse and each light of sagittal surface is all less than 0.05mm; 3C shows the MTF family curve of the embodiment of the present invention, finds out that, when object distance 300mm, the MTF of each visual field all reaches diffraction limit, from curve at spatial frequency 100lp/mm place mtf value more than 0.4; 3D shows the MTF curve of the embodiment of the present invention when object distance 250mm, as seen from the figure now at spatial frequency 100lp/mm place mtf value about 0.3; 3E shows the MTF curve of the embodiment of the present invention when object distance 360mm, as seen from the figure now at spatial frequency 100lp/mm place mtf value about 0.3; As can be seen from above optical indicatrix figure, the imaging lens distortion of the present embodiment is little, have higher image quality, and field depth is wide.

On the other hand, the invention provides a kind of iris imaging module, as shown in Figure 2 and Figure 4, comprise above-mentioned arbitrary imaging lens and be positioned at the imageing sensor 8 ' (8 ") at this imaging lens rear, and this imageing sensor 8 ' (8 ") be CCD or cmos sensor.Iris imaging module of the present invention has higher image quality at near-infrared band, distorts little; Structure is simple, and easy to assembly, cost is low; Be particularly useful for binocular iris capturing, require low to the fitness of user.

Again on the one hand, the invention provides a kind of iris identification device, wrap the hardware circuit stated iris imaging module and be connected with this iris imaging module.Iris identification device of the present invention has higher image quality at near-infrared band, distorts little; Structure is simple, and easy to assembly, cost is low; Be particularly useful for binocular iris capturing, require low to the fitness of user.

The above is the preferred embodiment of the present invention; it should be pointed out that for those skilled in the art, under the prerequisite not departing from principle of the present invention; can also make some improvements and modifications, these improvements and modifications also should be considered as protection scope of the present invention.

Claims (10)

1. an imaging lens, is characterized in that, comprises successively from front to back along light direction:

First lens, described first lens are the biconvex lens with positive light coke, and its front surface is convex surface, and rear surface is convex surface;

Second lens, described second lens are the meniscus with positive light coke, and its front surface is convex surface, and rear surface is concave surface;

3rd lens, described 3rd lens are the meniscus with negative power, and its front surface is convex surface, and rear surface is concave surface;

4th lens, described 4th lens are the meniscus with positive light coke, and its front surface is convex surface, and rear surface is concave surface;

5th lens, described 5th lens are the biconvex lens with positive light coke, and its front surface is convex surface, and rear surface is convex surface;

Described 4th lens and the 5th lens glue are combined.

2. imaging lens according to claim 1, is characterized in that, 1.8f≤f1≤2.3f, 0.45f≤f2≤1.1f ,-0.55f≤f3≤-0.33f, 1.05f≤f4≤1.35f, 0.9f≤f5≤1.67f; Wherein, f is total focal length of imaging lens, and f1 is first focal length of lens, and f2 is second focal length of lens, and f3 is the 3rd focal length of lens, and f4 is the 4th focal length of lens, and f5 is the 5th focal length of lens.

3. imaging lens according to claim 1, is characterized in that, 17mm≤f1≤21mm, 4mm≤f2≤9.5mm ,-5mm≤f3≤-3mm, 9.5mm≤f4≤12mm, 8mm≤f5≤15mm; 200mm≤h≤400mm, Δ h >=110mm; Wherein, h is object distance, and Δ h is object space field depth, Δ h=object space shooting distance farthest-object space minimum photographic distance.

4. imaging lens according to claim 1, is characterized in that, the material of described first lens, the second lens, the 3rd lens, the 4th lens and the 5th lens meets: 1.6≤nd≤1.8,25≤vd≤55, wherein, nd is the refractive index of lens material, and vd is the abbe number of lens material.

5. the imaging lens according to the arbitrary claim of claim 1-4, is characterized in that, is provided with the diaphragm for controlling near infrared light percent of pass between described 3rd lens and the 4th lens.

6. imaging lens according to claim 5, is characterized in that, the front surface of described first lens is coated with can reflect visible light through the filter coating of near infrared light; Front surface and the rear surface of the rear surface of described first lens and described second lens, the 3rd lens, the 4th lens and the 5th lens are all coated with the near-infrared band anti-reflection film that can strengthen near infrared light transmitance.

7. imaging lens according to claim 5, is characterized in that, or described imaging lens also comprises can reflect visible light through the optically flat filter of near infrared light; Front surface and the rear surface of described first lens, the second lens, the 3rd lens, the 4th lens and the 5th lens are all coated with the near-infrared band anti-reflection film that can strengthen near infrared light transmitance.

8. imaging lens according to claim 5, is characterized in that, the material of described first lens, the second lens, the 3rd lens, the 4th lens and the 5th lens is glass.

9. an iris imaging module, is characterized in that, comprise the imaging lens described in the arbitrary claim of claim 1-8 and be positioned at the imageing sensor at described imaging lens rear, described imageing sensor is CCD or cmos sensor.

10. an iris identification device, is characterized in that, the hardware circuit comprising iris imaging module according to claim 9 and be connected with described iris imaging module.