US20150009580A1

US20150009580A1 - Ultra-wide-angle imaging lens assembly with five lenses

Info

Publication number: US20150009580A1
Application number: US14/056,103
Authority: US
Inventors: Hung-Wen Lee
Original assignee: Ability Opto Electronics Technology Co Ltd
Current assignee: Ability Opto Electronics Technology Co Ltd
Priority date: 2013-07-02
Filing date: 2013-10-17
Publication date: 2015-01-08
Anticipated expiration: 2033-10-17
Also published as: TW201502635A; CN104280862A; TWI474070B; US8928999B1; EP2821833A1

Abstract

An imaging lens assembly comprises a fixing diaphragm and an optical set including five lenses. An arranging order from an object side to an image side is: a first lens; a second lens; a third lens having a lens with a positive refractive power defined near the optical axis and a convex surface directed toward the image side; a fourth lens having a lens with a positive refractive power defined near the optical axis and a convex surface directed toward the image side; and a fifth lens having a concave surface with a corrugated contour directed toward the image side and disposed near the optical axis. At least one surface of the five lenses is aspheric. By the concatenation between the lenses and the adapted curvature radius, thickness, interval, refractivity, and Abbe numbers, the assembly attains a big diaphragm with ultra-wide-angle, a shorter height, and a better optical aberration.

Description

The current application claims a foreign priority to the patent application of Taiwan No. 102123562 filed on Jul. 2, 2013.

BACKGROUND OF THE INVENTION

1. Field of the Invention
The present invention relates to an ultra-wide-angle imaging lens assembly with five lenses, in particular to a lens structure attaining a big diaphragm, a shorter height, and a high resolution by curvature, interval and optical parameter between each lens.
2. Description of the Related Art
The conventional lens structure adopts an image display lens assembly which is applied to smart phone, tablet PC, cell phone, notebook, and webcam. The electronic products are developed to become lighter, thinner, shorter, and smaller and provide with higher efficiency. A video sensor of the image display lens assembly, such as Charge Coupled Device (CCD) or Complementary Metal Oxide Semiconductor (CMOS), is also developed for more pixels, so the lens structure is ceaselessly developed to be provided with compactness and higher resolution.
Therefore, the present invention is disclosed in accordance with an ultra-wide-angle lens structure with multi-lens for a demand of the development of the image display lens assembly, especially to an imaging lens assembly of a lens structure with at least five lenses.

SUMMARY OF THE INVENTION

In view of the conventional ultra-wide-angle lens structure with multi-lens that has big volume and lack of efficiency, an ultra-wide-angle imaging lens assembly with five lenses is disclosed.
It is an object of the present invention to provide an ultra-wide-angle imaging lens assembly with five lenses, which comprises a fixing diaphragm and an optical set. The optical set includes a first lens, a second lens, a third lens, a fourth lens, and a fifth lens. An arranging order thereof from an object side to an image side is: the first lens with a negative refractive power defined near an optical axis and a convex surface directed toward the object side, and at least one surface of the first lens is aspheric; the second lens with a positive refractive power defined near the optical axis and a convex surface directed toward the object side, and at least one surface of the second lens is aspheric; the fixing diaphragm; the third lens having a lens with a positive refractive power defined near the optical axis and a convex surface directed toward the image side, and at least one surface of the third lens is aspheric; the fourth lens having a lens with a positive refractive power defined near the optical axis and convex surfaces directed toward the image side, and at least one surface of the fourth lens is aspheric; and the fifth lens having a concave surface with a corrugated contour directed toward the image side and disposed near the optical axis, and at least one surface of the fifth lens is aspheric.
The imaging lens assembly satisfies the following conditional expression: 2.5<TL/f<3.5. The TL is defined as a distance from a top point of the object side of the first lens to an imaging surface side. The f is defined as a focal length of the entire lens assembly.
A shape of the aspheric surface satisfies a formula of:
$z = \frac{{ch}^{2}}{\begin{matrix} 1 + {[1 - (k + 1) c^{2} h^{2}]}^{0.5} + \\ {Hh}^{18} + {Jh}^{20} + \dots \end{matrix}} + {Ah}^{4} + {Bh}^{6} + {Ch}^{8} + {Dh}^{10} + {Eh}^{12} + {Fh}^{14} + {Gh}^{16}$
The z is defined as a position value about a location at a height of h along a direction of the optical axis referring to a surface top point. The k is defined as a conic constant. The c is a reciprocal of a radius of a curvature. The A, B, C, D, E, F, G, etc. are defined as high-order aspheric surface coefficients.
The present invention is characterized in that a lens structure attains a big diaphragm with ultra-wide-angle, a shorter height, and a high resolution by curvature, interval, and optical parameter between each lens.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view showing an optical structure of a first preferred embodiment of the present invention;

FIG. 2 is a schematic view showing a spherical aberration of the first preferred embodiment of the present invention;

FIG. 3 is a schematic view showing an astigmatic aberration of the first preferred embodiment of the present invention;

FIG. 4 is a schematic view showing a distorted aberration of the first preferred embodiment of the present invention;

FIG. 5 is a schematic view showing an optical structure of a second preferred embodiment of the present invention;

FIG. 6 is a schematic view showing a spherical aberration of the second preferred embodiment of the present invention;

FIG. 7 is a schematic view showing an astigmatic aberration of the second preferred embodiment of the present invention;

FIG. 8 is a schematic view showing a distorted aberration of the second preferred embodiment of the present invention;

FIG. 9 is a schematic view showing an optical structure of a third preferred embodiment of the present invention;

FIG. 10 is a schematic view showing a spherical aberration of the third preferred embodiment of the present invention;

FIG. 11 is a schematic view showing an astigmatic aberration of the third preferred embodiment of the present invention;

FIG. 12 is a schematic view showing a distorted aberration of the third preferred embodiment of the present invention;

FIG. 13 is a schematic view showing an optical structure of a fourth preferred embodiment of the present invention;

FIG. 14 is a schematic view showing a spherical aberration of the fourth preferred embodiment of the present invention;

FIG. 15 is a schematic view showing an astigmatic aberration of the fourth preferred embodiment of the present invention; and

FIG. 16 is a schematic view showing a distorted aberration of the fourth preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Before describing in detail, it should note that the like elements are denoted by the similar reference numerals throughout disclosure.
The present invention provides an ultra-wide-angle imaging lens assembly with five lenses, in particular to a lens structure attaining a big diaphragm with ultra-wide-angle, a shorter height, and a high resolution by a curvature, an interval, an optical parameter between each lens, and a fixing diaphragm 30 disposed between a second lens 20 and a third lens 40.
Referring to FIG. 1, a schematic view of an optical structure of an ultra-wide-angle imaging lens assembly with five lenses is shown. The structure of the imaging lens comprises the fixing diaphragm 30 and an optical set. The optical set includes a first lens 10, a second lens 20, a third lens 40, a fourth lens 50, and a fifth lens 60. An arranging order thereof from an object side to an image side is: the first lens 10 with a negative refractive power defined near an optical axis and a convex surface directed toward the object side, and at least one surface of the first lens 10 is aspheric; the second lens 20 with a positive refractive power defined near the optical axis and a convex surface directed toward the object side, and at least one surface of the second lens 20 is aspheric; the fixing diaphragm 30; the third lens 40 having a lens with a positive refractive power defined near the optical axis and a convex surface directed toward the image side, and at least one surface of the third lens 40 is aspheric; the fourth lens 50 having a lens with a positive refractive power defined near the optical axis and convex surfaces directed toward the image side, and at least one surface of the fourth lens 50 is aspheric; the fifth lens 60 having a concave surface with a corrugated contour directed toward the image side and disposed near the optical axis, and at least one surface of the fifth lens 60 is aspheric; a filter unit 70 filtering light with specific wave length and adopted by an infrared stopping filter unit applied to a visible light image; and an image sensor 80 (an imaging surface side) used for receiving a digital signal transformed by an infrared invisible light image of the filter.
The imaging lens assembly satisfies the following conditional expression: 2.5<TL/f<3.5. The TL is defined as a distance from a top point of the object side of the first lens to the imaging surface side. The f is defined as a focal length of the entire lens assembly.
The first lens 10 includes a first surface 11 facing an object side and a second surface 12 facing the imaging surface side. The first surface 11 is defined as a convex surface disposed near the optical axis opposite to the object side. The second surface 12 is defined as a concave surface disposed near the optical axis opposite to the imaging surface side. The second lens 20 includes a third surface 21 facing the object side and a fourth surface 22 facing the imaging surface side. The third surface 21 is defined as a convex surface disposed near the optical axis opposite to the object side. The fourth surface 22 is defined as a concave surface disposed near the optical axis opposite to the imaging surface side. The third lens 40 includes a fifth surface 41 facing the object side and a sixth surface 42 facing the imaging surface side. The fifth surface 41 is defined as a convex surface disposed near the optical axis opposite to the object side. The sixth surface 42 is defined as a convex surface disposed near the optical axis opposite to the imaging surface side. The fourth lens 50 includes a seventh surface 51 facing the object side and an eighth surface 52 facing the imaging surface side. The seventh surface 51 is defined as a convex surface disposed near the optical axis opposite to the object side. The eighth surface 52 is defined as a convex surface disposed near the optical axis opposite to the imaging surface side. The fifth lens 60 includes a ninth surface 61 facing the object side and a tenth surface 62 facing the imaging surface side. The ninth surface 61 is defined as a concave surface disposed near the optical axis opposite to the object side. The tenth surface 62 is defined as a concave surface disposed near the optical axis opposite to the imaging surface side. At least one surface of the first lens 10, the second lens 20, the third lens 40, the fourth lens 50, and fifth lens 60 is aspheric, thereby correcting the spherical aberration and the image aberration for having a characteristic of low tolerance sensitivity.
A shape of the aspheric surface of the imaging lens assembly satisfies a formula of:
$z = \frac{{ch}^{2}}{\begin{matrix} 1 + {[1 - (k + 1) c^{2} h^{2}]}^{0.5} + \\ {Hh}^{18} + {Jh}^{20} + \dots \end{matrix}} + {Ah}^{4} + {Bh}^{6} + {Ch}^{8} + {Dh}^{10} + {Eh}^{12} + {Fh}^{14} + {Gh}^{16}$
The z is defined as a position value about a location at a height of h along a direction of the optical axis referring to a surface top point. The k is defined as a conic constant. The c is a reciprocal of a radius of a curvature. The A, B, C, D, E, F, G, etc. are defined as high-order aspheric surface coefficients.
In an ultra-wide-angle micro-optical image capturing device of the present invention, the fixing diaphragm 30 is disposed between the object and the third lens 40 for getting an incident beam. The first lens 10 is adopted by a lens with a negative refractive power defined near the optical axis and the second lens 20, the third lens 40, and the fourth lens 50 are adopted by lenses with a positive refractive power defined near the optical axis. The first lens 10 adopts the first surface 11 convexly defined toward the object side and disposed near the optical axis for assembling the external incident beam with ultra-wide-angle and keeping the beam on the second surface 12 of the first lens 10, thereby presenting a function of the aspheric surface, correcting the aberration, reducing the tolerance sensitivity, and rendering the device have ultra-wide-angle with an image-capture angle over 100°. The third surface 21 defined on the second lens 20 as a convex surface disposed near the optical axis opposite to the object side is then expanded. The fourth surface 22 is defined as a lens with a positive refractive power and a concave surface disposed near the optical axis opposite to the imaging surface side. The fourth lens 50 radiates via the seventh surface 51 that is concavely defined toward the imaging surface side and disposed near the optical axis, so that the beam is able to be spread on the tenth surface 62 of the fifth lens 60 with a larger dimension. That is to say, the incident beam is expanded by the third surface 21 for being spread on the tenth surface 62 with a larger dimension, thereby presenting the function of aspheric surface, correcting the aberration, and reducing tolerance sensitivity.
The aspheric surface not only corrects the spherical aberration and the image aberration but also includes the fixing diaphragm 30 disposed between the second lens 20 and the third lens 40, thereby reducing the full length of the lens optical system. The first lens 10, the second lens 20, the third lens 40, the fourth lens 50, and the fifth lens 60 are preferably adopted by plastic, which is conducive to eliminate the aberration and reduce the weight of the lens. The entire optical system consists of five plastic lenses and benefits a mass production. The optical system also provides with the low tolerance sensitivity to meet a requirement of the mass production. The filter unit 70 used for filtering infrared invisible light and allowing visible light forms an ultra-wide-angle micro-optical image capturing device capable of capturing the sight that people see.
By the concatenation between the above-mentioned surfaces of lenses and the adapted curvature radius, thickness, interval, refractivity, and Abbe numbers, the assembly attains a big diaphragm with ultra-wide-angle, a shorter height, and a better optical aberration.

First Preferred Embodiment of the Present Invention

Due to the above-mentioned technique of the present invention, it is able to be practiced in accordance with the following values:

Basic lens data of the first preferred embodiment

	Curvature	Thickness/	Refrac-	Abbe
	radius	Interval	tivity	number
Surfaces	(Radius)	(Thickness)	(Nd)	(Vd)

First	First	19.5	0.26	1.544100	56.093602
lens 10	surface 11
	Second	0.97	0.35
	surface 12
Second	Third	0.78	0.47	1.635500	23.891420
lens 20	surface 21
	Fourth	1.08	0.17
	surface 22

Fixing diaphragm 30

∞

−0.02

Third	Fifth	2.98	0.67	1.544100	56.093602
lens 40	surface 41
	Sixth	−1.99	0.07
	surface 42
Fourth	Seventh	1.90	0.68	1.544100	56.093602
lens 50	surface 51
	Eighth	−0.57	0.11
	surface 52
Fifth	Ninth	−1.14	0.25	1.635500	23.891420
lens 60	surface 61
	Tenth	1.31	0.17
	surface 62
Filter	Eleventh	∞	0.3	1.516800	64.167336
unit 70	surface 71
	Twelfth	∞	0.28
	surface 72

The filter unit 70 has a thickness of 0.3 mm and is adopted by an infrared stopping filter unit. A wave length of the light passing therethrough is 450-650 mm.
A shape of the above-mentioned aspheric surface satisfies the following formula:
$z = \frac{{ch}^{2}}{\begin{matrix} 1 + {[1 - (k + 1) c^{2} h^{2}]}^{0.5} + \\ {Hh}^{18} + {Jh}^{20} + \dots \end{matrix}} + {Ah}^{4} + {Bh}^{6} + {Ch}^{8} + {Dh}^{10} + {Eh}^{12} + {Fh}^{14} + {Gh}^{16}$
The z is defined as a position value about a location at a height of h along a direction of the optical axis referring to a surface top point. The k is defined as a conic constant. The c is a reciprocal of a radius of a curvature. The A, B, C, D, E, F, G etc. are defined as high-order aspheric surface coefficients.
The values of quadratic surface coefficient of the aspheric surface of the first preferred embodiment are listed as follows:
The first surface 11 (k=−99):
A: 0.120860
B: −0.043532
C: 0.024980
D: −0.008249
E: 0.001732
F: 0.000000
G: 0.000000
The second surface 12 (k=−1.12):
A: −0.270255
B: 0.366500
C: −0.243760
D: 0.054755
E: 0.000000
F: 0.000000
G: 0.000000
The third surface 21 (k=−0.86):
A: −0.256389
B: −0.002088
C: 0.646003
D: −0.790538
E: 0.000000
F: 0.000000
G: 0.000000
The fourth surface 22 (k=3.63):
A: 0.003768
B: 0.776136
C: −1.322913
D: 26.150389
E: −0.000185
F: 0.000000
G: 0.000000
The fifth surface 41 (k=−71.92):
A: 0.253812
B: 1.588127
C: −19.307721
D: 76.868704
E: 2.378378e-013
F: 0.000000
G: 0.000000
The sixth surface 42 (k=−104.03):
A: −2.222512
B: 4.950060
C: −14.441919
D: 18.218801
E: 0.000000
F: 0.000000
G: 0.000000
The seventh surface 51 (k=0.00):
A: −0.623089
B: −0.269938
C: −0.310977
D: −2.024637
E: 0.000000
F: 0.000000
G: 0.000000
The eighth surface 52 (k=−5.26):
A: 0.642975
B: −2.022728
C: 1.131730
D: −0.181891
E: 0.000000
F: 0.000000
G: 0.000000
The ninth surface 61 (k=−29.61):
A: 0.351190
B: −3.811852
C: 4.918355
D: −2.252320
E: −0.502655
F: 0.832491
G: 0.000000
The tenth surface 62 (k=0.00):
A: −0.731992
B: 0.178817
C: 0.004144
D: 0.032295
E: −0.056005
F: 0.015918
G: 0.000000
According to the above-mentioned values, the related exponent of performance of the micro-image capturing lens is: f=1.296 mm; TL=3.76 mm; TL/f=2.90.
Referring to FIG. 2, a schematic view of a spherical aberration of the first preferred embodiment of the present invention is shown. Referring to FIG. 3, a schematic view of an astigmatic aberration of the first preferred embodiment of the present invention is shown. Referring to FIG. 4, a schematic view of a distorted aberration of the first preferred embodiment of the present invention is shown. The measured astigmatic aberration, distorted aberration, and spherical aberration are in the standard scope and have a good optical performance and imaging quality according to the above-mentioned figures.

Second Preferred Embodiment of the Present Invention

Basic lens data of the second preferred embodiment

First	First	2.95	0.28	1.514600	57.17778
lens 10	surface 11
	Second	0.80	0.11
	surface 12
Second	Third	1.14	0.58	1.635500	23.891420
lens 20	surface 21
	Fourth	1.38	0.21
	surface 22

Fixing diaphragm 30

∞

0.01

Third	Fifth	4.24	0.49	1.514600	57.17778
lens 40	surface 41
	Sixth	−0.68	0.22
	surface 42
Fourth	Seventh	−0.68	0.33	1.544100	56.093602
lens 50	surface 51
	Eighth	−0.64	0.14
	surface 52
Fifth	Ninth	1.81	0.62	1.544100	56.093602
lens 60	surface 61
	Tenth	1.40	0.20
	surface 62
Filter	Eleventh	∞	0.3	1.516800	64.167336
unit 70	surface 71
	Twelfth	∞	0.25
	surface 72

The filter unit 70 has a thickness of 0.3 mm and is adopted by an infrared stopping filter unit. A wave length of the light passing therethrough is 450-650 mm.
The values of quadratic surface coefficient of the aspheric surface of the second preferred embodiment are listed as follows:
The first surface 11 (k=−8.09):
A: −0.076364
B: 0.052546
C: 0.020178
D: −0.024610
E: 0.007741
F: 0.000000
G: 0.000000
The second surface 12 (k=−0.17):
A: −0.114338
B: −0.482088
C: −0.006313
D: 0.098751
E: −0.243835
F: 0.000000
G: 0.000000
The third surface 21 (k=−0.36):
A: 0.486100
B: −0.150616
C: 0.378690
D: 0.979435
E: −1.427587
F: 0.000000
G: 0.000000
The fourth surface 22 (k=0.87):
A: 1.591932
B: −1.186978
C: 39.642648
D: −66.463202
E: −3.229075e-005
F: 0.000000
G: 0.000000
The fifth surface 41 (k=−98.81):
A: 0.032717
B: 0.777552
C: −23.946204
D: 4.880313
E: −6.788012e-011
F: 0.000000
G: 0.000000
The sixth surface 42 (k=0.62):
A: 0.654822
B: 0.046021
C: −6.859322
D: 17.213693
E: 0.000000
F: 0.000000
G: 0.000000
The seventh surface 51 (k=0.00):
A: 2.266994
B: −4.190758
C: 8.167473
D: −5.982716
E: 0.000000
F: 0.000000
G: 0.000000
The eighth surface 52 (k=−2.68):
A: 0.030632
B: −1.016005
C: 3.782609
D: −2.510238
E: 0.000000
F: 0.000000
G: 0.000000
The ninth surface 61 (k=−3.77):
A: −0.312190
B: −0.883667
C: 1.030004
D: −0.418662
E: −0.845494
F: 1.058650
G: 0.000000
The tenth surface 62 (k=0.00):
A: −0.468743
B: 0.245303
C: −0.261756
D: 0.117260
E: −0.008273
F: −0.008623
G: 0.000000
According to the above-mentioned values, the related exponent of performance of the micro-image capturing lens is: f=1.259 mm; TL=3.75 mm; TL/f=2.98.
Referring to FIG. 6, a schematic view of a spherical aberration of the second preferred embodiment of the present invention is shown. Referring to FIG. 7, a schematic view of an astigmatic aberration of the second preferred embodiment of the present invention is shown. Referring to FIG. 8, a schematic view of a distorted aberration of the second preferred embodiment of the present invention is shown. The measured astigmatic aberration, distorted aberration, and spherical aberration are in the standard scope and have a good optical performance and imaging quality according to the above-mentioned figures.

Third Preferred Embodiment of the Present Invention

Basic lens data of the third preferred embodiment

First	First	19.5	0.26	1.544100	56.093602
lens 10	surface 11
	Second	0.97	0.34
	surface 12
Second	Third	0.80	0.51	1.635500	23.891420
lens 20	surface 21
	Fourth	1.10	0.18
	surface 22

Fixing diaphragm 30

∞

−0.02

Third	Fifth	2.74	0.64	1.544100	56.093602
lens 40	surface 41
	Sixth	−1.73	0.09
	surface 42
Fourth	Seventh	1.98	0.66	1.544100	56.093602
lens 50	surface 51
	Eighth	−0.62	0.11
	surface 52
Fifth	Ninth	−1.29	0.25	1.635500	23.891420
lens 60	surface 61
	Tenth	1.28	0.16
	surface 62
Filter	Eleventh	∞	0.3	1.516800	64.167336
unit 70	surface 71
	Twelfth	∞	0.28
	surface 72

The filter unit 70 has a thickness of 0.3 mm and is adopted by an infrared stopping filter unit. A wave length of the light passing therethrough is 450-650 mm.
The values of quadratic surface coefficient of the aspheric surface of the third preferred embodiment are listed as follows:
The first surface 11 (k=−99.00):
A: 0.130411
B: −0.048831
C: 0.029435
D: −0.009632
E: 0.001812
F: 0.000000
G: 0.000000
The second surface 12 (k=−1.20):
A: −0.263159
B: 0.388136
C: −0.248846
D: 0.055115
E: 0.000000
F: 0.000000
G: 0.000000
The third surface 21 (k=−0.98):
A: −0.285573
B: 0.052920
C: 0.420778
D: −0.239140
E: 0.000000
F: 0.000000
G: 0.000000
The fourth surface 22 (k=4.18):
A: −0.112307
B: 0.704359
C: −2.495231
D: 25.597552
E: −0.000185
F: 0.000000
G: 0.000000
The fifth surface 41 (k=−36.93):
A: 0.118304
B: 0.840681
C: −10.241149
D: 36.590378
E: 2.695598e-013
F: 0.000000
G: 0.000000
The sixth surface 42 (k=−13.70):
A: −1.726404
B: 2.135053
C: −6.597376
D: 9.068656
E: 0.000000
F: 0.000000
G: 0.000000
The seventh surface 51 (k=0.00):
A: −0.848774
B: 0.389382
C: −2.197055
D: −0.133761
E: 0.000000
F: 0.000000
G: 0.000000
The eighth surface 52 (k=−6.49):
A: 0.444448
B: −2.133344
C: 1.450184
D: −0.252467
E: 0.000000
F: 0.000000
G: 0.000000
The ninth surface 61 (k=−36.35):
A: 0.145604
B: −3.714141
C: 4.606180
D: −1.813766
E: −0.502655
F: 0.832491
G: 0.000000
The tenth surface 62 (k=0.00):
A: −0.819487
B: 0.253437
C: −0.037115
D: 0.021567
E: −0.045731
F: 0.016789
G: 0.000000
According to the above-mentioned values, the related exponent of performance of the micro-image capturing lens is: f=1.30 mm; TL=3.76 mm; TL/f=2.89.
Referring to FIG. 10, a schematic view of a spherical aberration of the third preferred embodiment of the present invention is shown. Referring to FIG. 11, a schematic view of an astigmatic aberration of the third preferred embodiment of the present invention is shown. Referring to FIG. 12, a schematic view of a distorted aberration of the third preferred embodiment of the present invention is shown. The measured astigmatic aberration, distorted aberration, the spherical aberration are in the standard scope and have a good optical performance and imaging quality according to the above-mentioned figures.

Fourth Preferred Embodiment of the Present Invention

Basic lens data of the fourth preferred embodiment

First	First	6.32	0.28	1.514600	57.17778
lens 10	surface 11
	Second	0.69	0.06
	surface 12
Second	Third	1.01	0.68	1.635500	23.891420
lens 20	surface 21
	Fourth	1.85	0.24
	surface 22

Fixing diaphragm 30

∞

0.00

Third	Fifth	3.36	0.51	1.514600	57.17778
lens 40	surface 41
	Sixth	−0.67	0.23
	surface 42
Fourth	Seventh	−0.66	0.31	1.534611	56.072163
lens 50	surface 51
	Eighth	−0.67	0.06
	surface 52
Fifth	Ninth	1.48	0.63	1.544100	56.093602
lens 60	surface 61
	Tenth	1.37	0.18
	surface 62
Filter	Eleventh	∞	0.3	1.516800	64.167336
unit 70	surface 71
	Twelfth	∞	0.28
	surface 72

The filter unit 70 has a thickness of 0.3 mm and is adopted by an infrared stopping filter unit. A wave length of the light passing therethrough is 450-650 mm.
The values of quadratic surface coefficient of the aspheric surface of the fourth preferred embodiment are listed as follows:
The first surface 11 (k=−99.00):
A: 0.006972
B: −0.007745
C: 0.018949
D: −0.008813
E: 0.001611
F: 0.000000
G: 0.000000
The second surface 12 (k=−0.56):
A: −0.252410
B: −0.273865
C: −0.091714
D: 0.058115
E: 0.021166
F: 0.000000
G: 0.000000
The third surface 21 (k=−0.51):
A: 0.152876
B: 0.211828
C: −0.332151
D: 1.046094
E: −0.786177
F: 0.000000
G: 0.000000
The fourth surface 22 (k=4.67):
A: 1.089271
B: 2.607324
C: −3.852920
D: 68.379090
E: −3.229066e-005
F: 0.000000
G: 0.000000
The fifth surface 41 (k=−47.35):
A: 0.028983
B: −1.366025
C: 1.640750
D: −103.018927
E: −1.878362e-012
F: 0.000000
G: 0.000000
The sixth surface 42 (k=0.56):
A: 0.535304
B: 0.319529
C: −6.568534
D: 15.800973
E: 0.000000
F: 0.000000
G: 0.000000
The seventh surface 51 (k=0.00):
A: 2.271573
B: −3.829659
C: 6.576384
D: −3.872465
E: 0.000000
F: 0.000000
G: 0.000000
The eighth surface 52 (k=−1.02):
A: 0.354082
B: −0.314642
C: 2.216538
D: −1.938111
E: 0.000000
F: 0.000000
G: 0.000000
The ninth surface 61 (k=−13.37):
A: −0.499153
B: −0.313673
C: 0.508271
D: −0.353739
E: −0.181652
F: 0.547204
G: 0.000000
The tenth surface 62 (k=0.00):
A: −0.612448
B: 0.424141
C: −0.330009
D: 0.082335
E: 0.034274
F: −0.021202
G: 0.000000
According to the above-mentioned values, the related exponent of performance of the micro-image capturing lens is: f=1.159 mm; TL=3.75 mm; TL/f=3.24.
Referring to FIG. 14, a schematic view of a spherical aberration of the fourth preferred embodiment of the present invention is shown. Referring to FIG. 15, a schematic view of an astigmatic aberration of the fourth preferred embodiment of the present invention is shown. Referring to FIG. 16, a schematic view of a distorted aberration of the fourth preferred embodiment of the present invention is shown. The measured astigmatic aberration, distorted aberration, the spherical aberration are in the standard scope and have a good optical performance and imaging quality according to the above-mentioned figures.
The micro-optical image capturing device utilizes a plurality of aspheric surface lens with five lenses, the front four lens of which have refractive power defined near the optical axis sequentially arranged as negative, positive, positive, and positive, and the filter unit 70 which filters a light with infrared wave length and allows the visible light with the demanded wave length. The filter unit 70 is preferably adopted by an infrared stopping filter unit applied to the visible light image.
By making use of the aspheric surface that corrects the aberration, reduces the tolerance sensitivity, and includes the fixing diaphragm 30 disposed between the second lens 20 and the third lens 40, not only the aberration is corrected but also the full length of the lens optical system is reduced. Further, the device provides with an ultra-wide-angle with an image capturing angle over 100°. The first, second, third, fourth, and fifth lenses are preferably adopted by plastic, which is conducive to eliminate the aberration and reduce the weight of the lens. The entire optical system consists of five plastic lenses and provides with the low tolerance sensitivity. The optical system is also easy to be manufactured and assembled and benefits a mass production. Furthermore, the optical system provides with a good imaging quality to meet the requirement of miniaturizing the portable image capturing products.
While we have shown and described the embodiment in accordance with the present invention, it should be clear to those skilled in the art that further embodiments may be made without departing from the scope of the present invention.

Claims

I claim:

1. An ultra-wide-angle imaging lens assembly with five lenses comprising a fixing diaphragm and an optical set; said optical set including a first lens, a second lens, a third lens, a fourth lens, and a fifth lens, an arranging order thereof from an object side to an image side being:

said first lens having a negative refractive power defined near an optical axis and a convex surface directed toward said object side; at least one surface of said first lens being aspheric;

said second lens having a positive refractive power defined near said optical axis and a convex surface directed toward said object side; at least one surface of said second lens being aspheric;

said fixing diaphragm;

said third lens having a lens with a positive refractive power defined near said optical axis and a convex surface directed toward said image side; at least one surface of said third lens being aspheric;

said fourth lens having a lens with a positive refractive power defined near said optical axis and a convex surface directed toward said image side; at least one surface of said fourth lens being aspheric; and

said fifth lens having a concave surface with a corrugated contour directed toward said image side and disposed near said optical axis; at least one surface of said fifth lens being aspheric.

2. The ultra-wide-angle imaging lens assembly with five lenses as claimed in claim 1 further satisfying the following expression: 2.5<TL/f<3.5, wherein said TL is defined as a distance from a top point of said object side of said first lens to an imaging surface side, and said f is defined as a focal length of said entire lens assembly.