CN204009207U

CN204009207U - 3D interactive projection camera lens

Info

Publication number: CN204009207U
Application number: CN201420177171.7U
Authority: CN
Inventors: 黄林; 戴付建
Original assignee: Zhejiang Sunny Optics Co Ltd
Current assignee: Zhejiang Sunny Optics Co Ltd
Priority date: 2014-04-13
Filing date: 2014-04-13
Publication date: 2014-12-10
Anticipated expiration: 2024-04-13

Abstract

The utility model provides a kind of projection lens, from imaging side to image source side, sequentially comprises: first lens group, the first lens that comprises a tool negative power, and a catoptrics face that makes light path bending; The second lens combination, the second lens that comprise a tool positive light coke, it is convex surface towards imaging side and image source side; The 3rd lens combination, the 3rd lens that comprise a tool negative power; The 4th lens combination has positive light coke, its one piece of comprising tool focal power or many pieces of eyeglasses, and the face of the most close imaging side is convex surface; Described camera lens meets following relationship: ImgH/D>0.55, and wherein, ImgH is half of image source diameter; D is that the face of first lens imaging side is to the vertical height of catoptrics face center.The utility model has adopted four groups of lens, and effectively the volume of reducing glass system, guarantees that camera lens has higher resolution with great visual angle in the situation that, realizes large field angle, little distortion and high-resolution technique effect.

Description

3D interactive projection camera lens

Technical field

The utility model relates to a kind of optical projection system being comprised of four groups of lens combination, especially relates to a kind of projection lens of the 3D of can be applicable to interactive system.

Background technology

In recent years, along with the continuous progress of science and technology, drive the progressively rise of 3D interactive device, the range of application of projection lens is also more and more wider.In order to be applicable to miniaturization electronic equipment, projection lens need to have enough field angle when guaranteeing miniaturization, with the occasion narrower and small, obtains larger picture.

Traditional projection lens is generally used for imaging, by adopting more eyeglass to eliminate various aberrations, to improve resolution, but can make projection lens total length elongated, is unfavorable for miniaturization; And general large field angle projection lens, distortion all can be larger, cannot meet high-resolution requirement.As the patent No. is " CN102879888A ", within open day, is the utility model patent of " 2013.1.16 ", this camera lens sequentially has seven eyeglasses and a total reflection prism, eyeglass number and the prism location of this camera lens, determined that this Lens cannot further dwindle, and can not meet the requirement of miniaturization.And for example in general zoom lens, prism can be placed between lens combination to reduce lens volume, but this structure cannot guarantee the heart characteristic far away of lens combination, makes the edge illumination of lens lower, cannot meet high-resolution requirement.

But 3D interactive device mainly relies on mask to produce signal through camera lens projection, then catches image through imaging lens, further by image processing software, information is extracted, thereby is realized the interactive functions such as multi-point touch, gesture identification.Therefore, the signal quality of projection lens simulation has conclusive effect to the precision of information extraction.And infrared band is because of the characteristic of himself, impact that can elimination visible ray, more easily realizes the extraction of information, reaches high-resolution requirement.As can be seen here, adopt infrared projection camera lens, effectively filtering parasitic light, improves resolution of lens.

Therefore, the utility model proposes a kind of application infrared band, and there is the projection lens of large field angle, little distortion and miniaturization.

Utility model content

In view of the above problems, the utility model proposes a kind of 3D interactive projection camera lens with large field angle, little distortion and miniaturization, and apply infrared band, reach the requirement of high score rate.Its technical scheme is as described below:

A 3D interactive projection camera lens, sequentially comprises from imaging side to image source side:

First lens group, only comprises the first lens of a tool negative power, and a catoptrics face that makes light path bending;

The second lens combination, only comprises the second lens of a tool positive light coke, and it is convex surface towards imaging side and image source side;

The 3rd lens combination, only comprises the 3rd lens of a tool negative power;

The 4th lens combination, has positive light coke, its one piece of comprising tool focal power or many pieces of eyeglasses, and the face of the most close imaging side is convex surface;

Described camera lens meets following relationship:

ImgH/D>0.55

Wherein, ImgH is half of image source diameter; D is that the face of first lens imaging side is to the vertical height of catoptrics face center.

Described camera lens meets following relationship:

-5.0<f3/f<0

Wherein, f3 is the focal length of the 3rd lens; F is the focal length of whole projection lens system;

Described the 3rd lens face is concave surface to image source side;

Between described first lens group and the second lens combination, be provided with diaphragm.

It is aspheric surface that described lens system has a face at least.

The utility model has adopted four groups of lens, by combining of eyeglass aspheric surface and sphere, and different focal powers is distributed, effectively dwindled the volume of camera lens, taken into full account the property taken into account of field angle and resolution, guaranteed that camera lens has good resolution with great visual angle in the situation that, realized large field angle, little distortion and wide-aperture technique effect, promoted the optical property of lens combination.

Accompanying drawing explanation

Fig. 1 is the primary structure schematic diagram of the embodiment 1 of the projection lens that provides of the utility model;

Fig. 2 is chromaticity difference diagram on the axle in embodiment 1 (mm);

Fig. 3 is the astigmatism figure (mm) in embodiment 1;

Fig. 4 is the distortion figure (%) in embodiment 1;

Fig. 5 is the ratio chromatism, figure (μ m) in embodiment 1;

Fig. 6 is the primary structure schematic diagram of the embodiment 2 of the projection lens that provides of the utility model;

Fig. 7 is chromaticity difference diagram on the axle in embodiment 2 (mm);

Fig. 8 is the astigmatism figure (mm) in embodiment 2;

Fig. 9 is the distortion figure (%) in embodiment 2;

Figure 10 is the ratio chromatism, figure (μ m) in embodiment 2;

Figure 11 is the primary structure schematic diagram of the embodiment 3 of the projection lens that provides of the utility model;

Figure 12 is chromaticity difference diagram on the axle in embodiment 3 (mm);

Figure 13 is the astigmatism figure (mm) in embodiment 3;

Figure 14 is the distortion figure (%) in embodiment 3;

Figure 15 is the ratio chromatism, figure (μ m) in embodiment 3;

Figure 16 is the primary structure schematic diagram of the embodiment 4 of the projection lens that provides of the utility model;

Figure 17 is chromaticity difference diagram on the axle in embodiment 4 (mm);

Figure 18 is the astigmatism figure (mm) in embodiment 4;

Figure 19 is the distortion figure (%) in embodiment 4;

Figure 20 is the ratio chromatism, figure (μ m) in embodiment 4;

Figure 21 is the primary structure schematic diagram of the embodiment 5 of the projection lens that provides of the utility model;

Figure 22 is chromaticity difference diagram on the axle in embodiment 5 (mm);

Figure 23 is the astigmatism figure (mm) in embodiment 5;

Figure 24 is the distortion figure (%) in embodiment 5;

Figure 25 is the ratio chromatism, figure (μ m) in embodiment 5.

Embodiment

A kind of interactive projection camera lens that the utility model provides, sequentially comprises from imaging side to image source side: first lens group, only comprise the first lens of a tool negative power, and a catoptrics face that makes light path bending; The second lens combination, only comprises the second lens of a tool positive light coke, and it is convex surface towards imaging side and image source side; The 3rd lens combination, only comprises the 3rd lens of a tool negative power; The 4th lens combination, has positive light coke, its one piece of comprising tool focal power or many pieces of eyeglasses, and the face of the most close imaging side is convex surface; It is aspheric surface that described lens system has a face at least; And be provided with diaphragm between first lens group and the second lens combination.

Wherein, this projection lens meets following relationship:

ImgH/D>0.55

-5.0<f3/f<0

Above-mentioned ImgH is half of image source diameter; D is that the face of first lens imaging side is to the vertical height of catoptrics face center; F3 is the focal length of the 3rd lens; F is the focal length of whole projection lens system.

Projection lens described in the utility model, this first lens group has the first lens of negative power, is conducive to expand field angle, guarantees the wide-angle characteristic of lens combination; Meanwhile, this first lens group comprises a catoptrics face, can make crooked about 90 degree of light path, effectively compresses the height dimension of camera lens.

And the diaphragm of described projection lens is between first lens group and the second lens combination, preferably diaphragm, between catoptrics face and the second lens combination, can further dwindle the height dimension of camera lens, guarantees the miniaturization of lens combination.

The second lens combination of described projection lens has positive light coke, and the 3rd lens combination has negative power, by the reasonable distribution of positive negative power, is conducive to revise the aberration of lens combination, improves the optical property of lens combination integral body.

The 4th lens combination of described projection lens has positive light coke, and the face of the most close imaging side is convex surface, can make the chief ray that is incident to imaging surface near the heart far away, guarantees better the brightness at projected image edge, reduces marginal aberration, improves the resolution of system.

Described projection lens meets relational expression ImgH/D>0.55, can effectively compress the height of lens combination, and shortens the overall length of lens combination, to reduce the volume of camera lens, realizes camera lens miniaturization, and fully guarantees the wide-angle of camera lens.

Described projection lens meets relational expression-5.0<f3/f<0, and the focal power of balanced system is distributed better, is conducive to the distortion of revisal wide angle system, guarantees the high resolving power of system.

In projection lens described in the utility model, having a face at least is aspheric surface, by adopting aspherical lens (particularly non-spherical glass lens), can effectively revise aberration, reduce the quantity of eyeglass that projection lens adopts, thereby reduce the overall length of lens combination.Simultaneously, by crooked light path, and configure rational focal power and distribute, can further compress the volume of camera lens, take into full account the property taken into account of field angle and resolution, guarantee that camera lens has higher resolution with great visual angle in the situation that, realize large field angle, little distortion and high-resolution technique effect, promote the optical property of lens combination.

With reference to the accompanying drawings above-mentioned utility model is specifically described:

As shown in Figure 1, in embodiment 1, this projection lens is sequentially comprised by imaging side to image source side: first lens group, only comprise the first lens E1 of a tool negative power, and a mirror lens E2 who makes light path bending; The second lens combination, only comprises the second lens E3 of a tool positive light coke, and it is convex surface towards imaging side and image source side; The 3rd lens combination, only comprises the 3rd lens E4 of a tool negative power, and it is concave surface towards image source side; The 4th lens combination, has positive light coke, and its one piece of comprising tool focal power or many pieces of eyeglasses are comprised the 4th lens E5 of tool positive light coke successively by imaging side to image source side, and it is convex surface towards imaging side, and the 5th lens E6 of tool positive light coke; Image source.Diaphragm is between first lens group and the second lens combination; It is aspheric surface that described projection lens system has a face at least.

From object space to image space, the two sides of first lens E1 is S1, S2, and diaphragm face is S3, the two sides of the second lens E3 is S4, S5, and the two sides of the 3rd lens E4 is S6, S7, and the two sides of the 4th lens E5 is S8, S9, the two sides of the 5th lens E6 is S10, S11, and image source is S12.

In embodiment 1, each parameter is as described below: TTL=13.06; F1=-2.455; F2=2.609; F3=-3.410; F4=5.544; F5=5.362; F=1.588;

ImgH/D=0.624；

f3/f=-2.147；

Systematic parameter: 1/6 " sensor devices f-number 1.8

Table 1

Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
						Sphere	Infinite	Infinite
Aspheric surface	8.2050	0.5000	1.85/40.6	4.2464	6.9204
						Aspheric surface	1.5929	0.8528		3.0600	-0.4493
Sphere	Infinite	3.0000	1.52/64.1	3.0153
						Sphere	Infinite	0.1000	7	2.0347
Sphere	Infinite	0.7498		1.9145
						Aspheric surface	3.1376	1.4360	1.59/61.0	3.5512	-0.1838
Aspheric surface	-2.4192	0.4873		3.6735	-1.6259
						Aspheric surface	-404.2476	1.7270	1.85/40.6	3.4048	-97.6361
Aspheric surface	2.8696	0.7646		3.1516	-0.9365
						Aspheric surface	8.6417	0.8560	1.85/40.6	3.6153	-50.1440
Aspheric surface	-9.4949	0.0989		3.8852	-82.2305
						Sphere	7.1721	1.1000	1.83/37.1	4.1291
Sphere	-10.4841	1.3831	6	4.1258
						Sphere	Infinite			3.5157

Following table is aspheric surface high-order term coefficient A4, A6, A8, A10, the A12 of non-spherical lens:

Table 2

A4	A6	A8	A10	A12
					9.2250E-03	-4.5301E-03	1.1896E-05	1.4984E-04	-1.5590E-05
-1.2089E-03	1.5046E-02	-1.9472E-02	5.7905E-03	-4.1902E-04
					-9.5193E-03	4.0872E-03	-1.5071E-03	-2.6683E-04	1.1220E-04
1.1241E-02	4.3396E-03	-1.3404E-03	-8.8847E-04	2.2082E-04
					-4.9999E-03	1.5683E-02	-6.0747E-03	3.1074E-04	9.0083E-05
-4.0659E-02	2.6807E-02	-3.5404E-03	-4.0118E-04	1.4011E-05
					1.0970E-03	-3.1206E-03	2.2663E-03	-6.0191E-04	4.4322E-05
7.8572E-03	5.0277E-04	-5.4719E-04	-4.2765E-05	1.2803E-05

Fig. 2 to Fig. 5 represents respectively chromaticity difference diagram on the axle in embodiment 1, astigmatism figure, distortion figure, ratio chromatism, figure, as can be seen from the figure the optical effect in embodiment 1.

As shown in Figure 6, in embodiment 2, this projection lens is sequentially comprised by imaging side to image source side: first lens group, only comprise the first lens E1 of a tool negative power, and a mirror lens E2 who makes light path bending; The second lens combination, only comprises the second lens E3 of a tool positive light coke, and it is convex surface towards imaging side and image source side; The 3rd lens combination, only comprises the 3rd lens E4 of a tool negative power, and it is concave surface towards image source side; The 4th lens combination, has positive light coke, and its one piece of comprising tool focal power or many pieces of eyeglasses are comprised the 4th lens E5 of tool positive light coke successively by imaging side to image source side, and it is convex surface towards imaging side, and the 5th lens E6 of tool positive light coke; Image source.Diaphragm is between first lens group and the second lens combination; It is aspheric surface that described projection lens system has a face at least.

In embodiment 2, each parameter is as described below: TTL=12.756; F1=-2.473; F2=2.546; F3=-3.789; F4=6.247; F5=5.362; F=1.588;

ImgH/D=0.623；

f3/f=-2.386；

Systematic parameter: 1/6 " sensor devices f-number 1.8

Table 3

Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
						Sphere	Infinite	Infinite
Aspheric surface	7.3327	0.5000	1.85/40.6	4.1989	6.1061
						Aspheric surface	1.5594	0.8528		3.0600	-0.4849
Sphere	Infinite	3.0000	1.52/64.2	3.0163
						Sphere	Infinite	0.1000		2.0244
Sphere	Infinite	0.7498		1.9035
						Aspheric surface	3.0411	1.4860	1.59/61.0	3.5386	-0.4182
Aspheric surface	-2.3427	0.1075		3.6828	-1.7298
						Aspheric surface	10.8976	1.7100	1.85/40.6	3.5017	5.2551
Aspheric surface	2.2745	1.0113		2.9375	-0.9189
						Aspheric surface	12.4485	0.8700	1.85/40.6	3.5247	-43.4116
Aspheric surface	-8.6733	0.1848		3.8065	-73.7675
						Sphere	7.1721	1.1000	1.83/37.2	4.0703
Sphere	-10.4841	1.0841		4.0588
						Sphere	Infinite			3.5270

Table 4

A4	A6	A8	A10	A12
					5.5868E-03	-3.7195E-03	4.1085E-05	9.5408E-05	-1.0538E-05
-9.1759E-04	1.0458E-02	-1.4586E-02	4.1872E-03	-3.6509E-04
					-7.1437E-03	3.2253E-04	-3.8273E-04	-1.9208E-04	6.3860E-05
1.1999E-02	2.9364E-03	-2.0697E-03	-3.1168E-04	1.3469E-04
					-7.9678E-03	1.0076E-02	-2.0951E-03	-6.5897E-04	1.8742E-04
-4.0315E-02	2.7724E-02	-5.4399E-03	2.1241E-03	-6.9421E-04
					1.9952E-03	-3.2264E-03	1.7674E-03	-4.9689E-04	4.7947E-05
8.9321E-03	6.9779E-04	-4.7533E-04	-1.8847E-04	3.6901E-05

Fig. 7 to Figure 10 represents respectively chromaticity difference diagram on the axle in embodiment 2, astigmatism figure, distortion figure, ratio chromatism, figure, as can be seen from the figure the optical effect in embodiment 2.

As shown in figure 11, in embodiment 3, this projection lens is sequentially comprised by imaging side to image source side: first lens group, only comprise the first lens E1 of a tool negative power, and a mirror lens E2 who makes light path bending; The second lens combination, only comprises the second lens E3 of a tool positive light coke, and it is convex surface towards imaging side and image source side; The 3rd lens combination, only comprises the 3rd lens E4 of a tool negative power, and it is concave surface towards image source side; The 4th lens combination, has positive light coke, and its one piece of comprising tool focal power or many pieces of eyeglasses are comprised the 4th lens E5 of tool positive light coke successively by imaging side to image source side, and it is convex surface towards imaging side, and the 5th lens E6 of tool positive light coke; Optical lens E7.Diaphragm is between first lens group and the second lens combination; It is aspheric surface that described projection lens system has a face at least.

From object space to image space, the two sides of first lens E1 is S1, S2, and diaphragm face is S3, the two sides of the second lens E3 is S4, S5, and the two sides of the 3rd lens E4 is S6, S7, and the two sides of the 4th lens E5 is S8, S9, the two sides of the 5th lens E6 is S10, S11, and the two sides of optical lens E7 is S12, S13.

In embodiment 3, each parameter is as described below: TTL=13.54; F1=-2.330; F2=2.752; F3=-4.790; F4=7.467; F5=5.362; F=1.588;

ImgH/D=0.619；

f3/f=-3.016；

Systematic parameter: 1/6 " sensor devices f-number 1.8

Table 5

Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
						Sphere	Infinite	Infinite
Aspheric surface	8.1198	0.5000	1.85/40.6	4.1976	6.4823
						Aspheric surface	1.5238	0.8528		3.0598	-0.5265
Sphere	Infinite	3.0000	1.52/64.2	3.0197
						Sphere	Infinite	0.1000		2.0880
Sphere	Infinite	0.7498		1.9704
						Aspheric surface	2.9720	1.4400	1.59/61.0	3.6486	-0.5943
Aspheric surface	-2.8169	0.5142		3.7613	-1.7202
						Aspheric surface	65.7114	1.5600	1.85/40.6	3.5437	1230.8692
Aspheric surface	3.7245	0.8508		2.9955	0.8460
						Aspheric surface	47.7812	0.5900	1.85/40.6	3.5342	-259.5627
Aspheric surface	-7.1192	0.4147		3.7057	-14.4133
						Sphere	7.1721	1.1000	1.83/37.2	4.0927
Sphere	-10.4841	0.3450		4.0925
						Sphere	Infinite	1.5240	1.46/67.8	3.9147
Sphere	Infinite			3.5159

Table 6

A4	A6	A8	A10	A12
					3.5892E-03	-3.0323E-03	1.8016E-04	4.7623E-05	-7.3180E-06
-6.1570E-03	9.6343E-03	-1.3034E-02	4.3650E-03	-5.6401E-04
					-1.8463E-03	-1.9886E-03	-9.7192E-05	2.8141E-05	8.6459E-06
9.0005E-03	-1.8229E-03	-3.3168E-04	2.0747E-05	1.7625E-05
					-7.8407E-03	4.0981E-03	-2.4462E-04	7.2653E-06	4.4577E-07
-2.6884E-02	8.3288E-03	1.5543E-03	5.6883E-05	1.2020E-04
					1.3203E-02	-3.4379E-03	1.2150E-04	1.5024E-04	-3.3040E-05
2.5195E-02	-4.7737E-04	-8.0971E-04	-2.0185E-04	4.5649E-05

Figure 12 to Figure 15 represents respectively chromaticity difference diagram on the axle in embodiment 3, astigmatism figure, distortion figure, ratio chromatism, figure, as can be seen from the figure the optical effect in embodiment 3.

As shown in figure 16, in embodiment 4, this projection lens is sequentially comprised by imaging side to image source side: first lens group, only comprise the first lens E1 of a tool negative power, and described first lens E1 can make light path crooked; The second lens combination, only comprises the second lens E2 of a tool positive light coke, and it is convex surface towards imaging side and image source side; The 3rd lens combination, only comprises the 3rd lens E3 of a tool negative power, and it is concave surface towards image source side; The 4th lens combination, has positive light coke, and its one piece of comprising tool focal power or many pieces of eyeglasses are comprised the 4th lens E4 of tool positive light coke successively by imaging side to image source side, and it is convex surface towards imaging side, and the 5th lens E5 of tool positive light coke; Image source.Diaphragm is between first lens group and the second lens combination; It is aspheric surface that described projection lens system has a face at least.

From object space to image space, the two sides of first lens E1 is S1, S2, and diaphragm face is S3, the two sides of the second lens E2 is S4, S5, and the two sides of the 3rd lens E3 is S6, S7, and the two sides of the 4th lens E4 is S8, S9, the two sides of the 5th lens E5 is S10, S11, and image source is S12.

In embodiment 4, each parameter is as described below: TTL=14.45; F1=-3.008; F2=2.526; F3=-3.834; F4=5.659; F5=3.902; F=1.504;

ImgH/D=0.776；

f3/f=-2.548；

Systematic parameter: 1/6 " sensor devices f-number 1.8

Table 7

Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
						Sphere	Infinite	Infinite
Aspheric surface	-12.5184	4.3675	1.52/64.2	8.0082	6.9204
						Aspheric surface	1.9554	2.1485		2.7615	-0.4493
Sphere	Infinite	0.4956		1.5310
						Aspheric surface	4.2178	1.2340	1.59/61.0	2.4091	-0.1838
Aspheric surface	-1.9950	0.2769		2.9934	-1.6259
						Aspheric surface	-14.8514	1.7270	1.85/40.6	3.2154	-97.6361
Aspheric surface	4.2876	0.7646		2.8689	-0.9365
						Aspheric surface	11.4285	0.8558	1.85/40.6	3.6094	-50.1440
Aspheric surface	-7.7625	0.1000		3.4846	-82.2305
						Sphere	5.6906	1.1000	1.83/37.2	3.7347
Sphere	-6.6195	1.3831		3.8422
						Sphere	Infinite			3.5908

Table 8

A4	A6	A8	A10	A12
					5.8351E-03	-6.8178E-04	5.4781E-05	-2.3595E-06	4.5633E-08
1.8393E-02	-4.0328E-02	3.5093E-02	-1.5301E-02	2.9490E-03
					-5.1867E-03	-9.4753E-03	1.3246E-03	1.5365E-02	-1.4049E-02
2.2000E-02	-6.7860E-03	2.1889E-02	-1.2274E-02	9.3874E-04
					-2.0410E-02	4.9558E-02	-2.1501E-02	5.2033E-03	-6.1326E-04
-7.7583E-02	3.0135E-02	8.4179E-03	-9.6630E-03	3.0369E-03
					-5.5528E-04	-1.7273E-03	3.9127E-03	-5.8610E-04	-2.7911E-06
2.3375E-02	6.6126E-03	-4.4019E-04	-1.7796E-04	2.3116E-05

Figure 17 to Figure 20 represents respectively chromaticity difference diagram on the axle in embodiment 4, astigmatism figure, distortion figure, ratio chromatism, figure, as can be seen from the figure the optical effect in embodiment 4.

As shown in figure 21, in embodiment 5, this projection lens is sequentially comprised by imaging side to image source side: first lens group, only comprise the first lens E1 of a tool negative power, and a mirror lens E2 who makes light path bending; The second lens combination, only comprises the second lens E3 of a tool positive light coke, and it is convex surface towards imaging side and image source side; The 3rd lens combination, only comprises the 3rd lens E4 of a tool negative power, and it is concave surface towards image source side; The 4th lens combination, the 4th lens E5 that comprises tool positive light coke, it is convex surface towards imaging side; Image source.Diaphragm is between first lens group and the second lens combination; It is aspheric surface that described projection lens system has a face at least.

From object space to image space, the two sides of first lens E1 is S1, S2, and diaphragm face is S3, and the two sides of the second lens E3 is S4, S5, and the two sides of the 3rd lens E4 is S6, S7, and the two sides of the 4th lens E5 is S8, S9, and image source is S10.

In embodiment 5, each parameter is as described below: TTL=13.52; F1=-2.226; F2=2.742; F3=-3.854; F4=3.689; F=1.594;

ImgH/D=0.598；

f3/f=-2.418；

Systematic parameter: 1/6 " sensor devices f-number 1.8

Table 9

Surface type	Radius-of-curvature	Thickness	Material	Effective aperture	Circular cone coefficient
						Sphere	Infinite	Infinite
Aspheric surface	7.7971	0.6211	1.85/40.6	4.6565	8.7588
						Aspheric surface	1.4447	1.0706		3.0911	-0.4652
Sphere	Infinite	3.0000	1.52/64.1	3.0242
						Sphere	Infinite	0.1000	7	2.2200
Sphere	Infinite	0.8488		2.1091
						Aspheric surface	3.1276	1.7775	1.59/61.0	3.8180	-0.2821
Aspheric surface	-2.5459	0.9628		4.0690	-1.5680
						Aspheric surface	429.4651	1.7696	1.85/40.6	3.3871	-1.06E+05
Aspheric surface	3.1830	0.9593		3.1378	-0.1397
						Aspheric surface	2.5983	1.5933	1.85/40.6	4.1232	-6.9567
Aspheric surface	12.0746	0.8224		3.7335	-459.7094
						Sphere	Infinite			3.8257

Table 10

A4	A6	A8	A10	A12
					8.8945E-03	-4.2112E-03	-1.8371E-05	1.3862E-04	-1.5366E-05
2.1951E-04	1.5590E-02	-1.9713E-02	5.1322E-03	-1.5813E-04
					-7.0393E-03	5.1334E-04	-7.0201E-04	-3.1657E-04	8.6727E-05
8.9070E-03	-3.3778E-03	1.1272E-03	-6.8030E-04	9.6936E-05
					-4.4967E-03	1.0199E-02	-6.0013E-03	5.7632E-04	1.0201E-04
-3.6084E-02	2.8405E-02	-4.9549E-03	-1.4190E-03	3.9804E-04
					-5.3371E-03	-3.0640E-03	3.8190E-03	-8.2399E-04	6.1675E-05
-4.0532E-02	8.5360E-03	2.0319E-04	1.7194E-05	2.4411E-05

Figure 22 to Figure 25 represents respectively chromaticity difference diagram on the axle in embodiment 5, astigmatism figure, distortion figure, ratio chromatism, figure, as can be seen from the figure the optical effect in embodiment 5.

Although described principle of the present utility model and embodiment for projection lens above; but under above-mentioned instruction of the present utility model; those skilled in the art can carry out various improvement and distortion on the basis of above-described embodiment, and these improvement or distortion all drop in protection domain of the present utility model.It will be understood by those skilled in the art that specific descriptions are above in order to explain the purpose of this utility model, and not for limiting the utility model, protection domain of the present utility model is limited by claim and equivalent thereof.

Claims

1. a 3D interactive projection camera lens, is characterized in that: from imaging side to image source side, sequentially comprise:

The 3rd lens combination, only comprises the 3rd lens of a tool negative power;

Described camera lens meets following relationship:

ImgH/D>0.55

2. 3D interactive projection camera lens according to claim 1, is characterized in that:

Described camera lens meets following relationship

-5.0<f3/f<0

Wherein, f3 is the focal length of the 3rd lens; F is the focal length of whole projection lens system.

3. 3D interactive projection camera lens according to claim 1, is characterized in that: described the 3rd lens face is concave surface to image source side.

4. 3D interactive projection camera lens according to claim 2, is characterized in that: described the 3rd lens face is concave surface to image source side.

5. according to claim 1,2,3 or 4 arbitrary described 3D interactive projection camera lenses, it is characterized in that: between described first lens group and the second lens combination, be provided with diaphragm.

6. 3D interactive projection camera lens according to claim 5, is characterized in that: it is aspheric surface that described lens system has a face at least.