CN107450168B - In dolly-out, dolly-back interchangeable tight shot - Google Patents

Abstract

Interchangeable of dolly-out,ing dolly-back in one kind tight shot, it include: the first eyeglass group and the second eyeglass group being arranged successively from the object side to image side, wherein: when shooting object from infinity to when short distance movement, the first eyeglass group is fixed, and the second eyeglass group is focused from image side to the movement of object side；First eyeglass group is made of for the cemented doublet with positive light coke or two independent eyeglasses with positive light coke and negative power.Second eyeglass group includes: the second eyeglass being arranged successively, third eyeglass, the 4th eyeglass, diaphragm, the 5th eyeglass and the 6th eyeglass, wherein: the second eyeglass, third eyeglass and the 6th eyeglass have positive light coke, 4th eyeglass and the 5th eyeglass have negative power, 5th eyeglass is cemented doublet, and the 6th eyeglass is aspherical lens；The present invention has rational design, in such a way that focusing is floated by rear group, weakens cell breath, and can reduce distortion, meets the camera lens demand of high-resolution film camera.

Description

In dolly-out, dolly-back interchangeable tight shot

Technical field

The present invention relates to a kind of video and the technology in film shooting field, it is specifically a kind of in interchangeable of dolly-out,ing dolly-back it is fixed Zoom lens.

Background technique

Cinema scene is exactly film shooting camera lens.Cinema scene not only possesses most top optics quality, but also its machine The design of tool structure has also fully taken into account the professional needs of film making, thus its is professional very strong.But due to movie mirror The design difficulty and manufacture difficulty of head are very high, and there are no a companys to release film truly at home so far Camera lens for shooting.Existing camera lens have the disadvantage that 1) resolution ratio is not high: the resolution ratio of film camera has been at present It can achieve 6K or 8K, but almost all of camera lens resolving power is not high on the market, can not match high-resolution Video camera uses；2) there is obvious dark angle: limitation and camera lens plating film water due to physical law (mainly reflection and the law of refraction) Flat limitation, all camera lenses more or less can all have dark angle；And camera lens are harsh not as good as cinema scene to the control at dark angle, because This dark angle is obvious, is unable to satisfy video and film shooting uses；3) distortion is big: the picture of dynamic image distorts often than quiet State photo seems to become apparent from, and pincushion or barrel distortion will once show shape at once when dynamic element occurs in picture, and It video camera subjectivity visual angle can be more serious when mobile；If the appearance within sweep of the eye of theater viewers too significantly distorts, Then it is possible that causing to move vertigo；So the image field of cinema scene must be as straight as possible；And often due to camera lens It is inadequate to the control of distortion, so being unable to satisfy cinema scene to the high request of distortion；4) cell breath is obvious: camera lens carries out pair Cell breath can be generated in burnt process, cell breath changes it in addition to the composition that can not almost discover for camera lens Outside, picture is not influenced by cell breath；And it carries out chasing after coke for film making, in picture or be moved between different subjects Burnt gimmick is very common, so very high to the requirement for inhibiting cell breath, general camera lens are unable to satisfy requirement.

Summary of the invention

The present invention In view of the above shortcomings of the prior art, proposes interchangeable tight shot of dolly-out,ing dolly-back in one kind, uses Group, which floats, afterwards focuses, and can meet the 8K resolution camera of matching silent frame and super35 picture, without obvious dark angle, distorts It is minimum, cell breath is faint, cost performance is high.

The present invention is achieved by the following technical solutions:

The present invention includes: the first eyeglass group and the second eyeglass group being arranged successively from the object side to image side, in which: works as subject When body is mobile to short distance from infinity, the first eyeglass group is fixed, and the second eyeglass group gathers from image side to the movement of object side It is burnt.

The first eyeglass group is cemented doublet with positive light coke or by with positive light coke and negative power Two independent eyeglass compositions.

The second eyeglass group includes: the second eyeglass being arranged successively, third eyeglass, the 4th eyeglass, diaphragm, the 5th mirror Piece and the 6th eyeglass, in which: the second eyeglass, third eyeglass and the 6th eyeglass have positive light coke, and the 4th eyeglass has negative light focus Degree, the 5th eyeglass have positive light coke, and the 5th eyeglass is cemented doublet.

The first eyeglass group and the second eyeglass group preferably satisfies: 2.5 < F_G1/F_G2< 3.5, in which: F_G1For the first eyeglass The whole focal length of group, F_G2For the whole focal length of the second eyeglass group.

The camera lens of the first eyeglass group and the second eyeglass group composition preferably satisfies: 0.3 < BFL/EFL < 0.7, in which: BFL is the optic back focal of camera lens, and EFL is the whole focal length of camera lens, by limiting the whole focal length of camera lens and the relationship of back focal length, So that the focal length of camera lens and rear burnt ratio are in a suitable range and reach the resolution ratio of 8k.

The first eyeglass group preferably satisfies: 2 < F_G1/ F < 12, in which: F_G1For the focal length of the camera lens the first eyeglass group, F For the camera lens whole focal length, be conducive to the tune of assembly and overall weight and center of gravity while camera lens is miniaturised It is whole.

5th eyeglass preferably satisfies: 0.2 < | N_D51-N_D52| < 0.5, in which: N_D51For the 5th with positive light coke Refractive index of the eyeglass close to object space side mirror piece, N_D52It is the 5th eyeglass with positive light coke close to the refractive index of image side eyeglass, 5th eyeglass can aid in the axial chromatic aberration and ratio chromatism, of correction camera lens, while compensate the spherical surface that the first eyeglass group is formed Aberration, and eliminate the ghost of camera lens.

6th eyeglass is aspherical lens, and the 6th eyeglass preferably satisfies: N_D6> 1.75, in which: N_D6It is the 6th Refractive index of the eyeglass relative to d line (λ=587.5600nm).

Technical effect

To solve the problems, such as that existing camera lens resolution ratio is inadequate, the present invention joined Glass aspheric mirror in camera lens Piece has been obviously improved resolving power and resolution ratio, enables the invention to the professional 8K for meeting at present highest resolution on the market The use of resolution camera.

To solve the problems, such as that existing camera lens have obvious dark angle, the present invention improves periphery light ratio in design.I.e. Make when aperture standard-sized sheet, periphery light ratio makes to present on picture more by the light of entire camera lens also 35% or more Uniformly, be conducive to Correct exposure when film shooting.

To solve the problems, such as that it is big that existing camera lens distort, present invention optimizes the structure of camera lens and optical paths, particularly plus The strong symmetry of camera lens rear end group, so that distortion is minimum, optical distortion is 1% hereinafter, ensure that picture from center to most Deforming and being distorted will not occur in periphery.

To solve the problems, such as that existing camera lens cell breath is obvious, the present invention is floated using rear group by the way of focusing. When shooting object from infinity to when short distance variation, pre-group is fixed, and rear group is focused from image space to object space movement.And Especially optimization diaphragm has accomplished that camera lens from when infinitely focusing as far as minimum distance, is drawn to optimal location at a distance from the eyeglass of front and back Face visual field changes within 3%, effectively to weaken cell breath.

Compared with prior art, the present invention is floated using rear group and is focused, and optimizes diaphragm at a distance from the eyeglass of front and back, effectively Weaken cell breath, the image for taking in camera lens is without obvious dark angle, and distorting, minimum, cell breath is faint, can meet and match complete draw The 8K resolution camera of width and super35 picture, low in cost, cost performance is high.

Detailed description of the invention

Fig. 1 is 1 optical texture schematic diagram of embodiment；

In figure: L1~L6 is the first to the 6th eyeglass, S1~S9, S11~S15 eyeglass mirror surface；

Fig. 2 is aberration diagram of the embodiment 1 relative to d line (λ=587.5600nm)；

In figure: (a) being spherical aberration, (b) be astigmatism curvature of field line, (c) be distortion aberration；

Fig. 3 is coma figure of the embodiment 1 relative to d line (λ=587.5600nm)；

In figure: tangential tangent line, field height height, sagittal radial line, ray aberrations light Aberration, img ht image height；

Fig. 4 is 2 optical texture schematic diagram of embodiment；

In figure: the first lens set of G1, L1~L7 are the first front lens to the 6th eyeglass, S1~S10, S12~S16 eyeglass mirror Face；

Fig. 5 is aberration diagram of the embodiment 2 relative to d line (λ=587.5600nm)；

In figure: (a) being spherical aberration, (b) be astigmatism curvature of field line, (c) be distortion aberration；

Fig. 6 is coma figure of the embodiment 2 relative to d line (λ=587.5600nm)；

In figure: tangential tangent line, field height height, sagittal radial line, ray aberrations light Aberration, img ht image height.

Specific embodiment

As shown in Figure 1, the present embodiment includes: the first eyeglass group G1 and the second eyeglass group being arranged successively from the object side to image side G2, in which: when shoot object it is mobile to short distance from infinity when, the first eyeglass group G1 is fixed, the second eyeglass group G2 from Image side is focused to the movement of object side.

The first eyeglass group G1 is the whole cemented doublet L1 with positive light coke, and wherein cemented doublet is towards object space The first front lens have positive light coke, towards image space the first rear lens have negative power.

The second eyeglass group G2 includes: the second eyeglass L2 being arranged successively, third eyeglass L3, the 4th eyeglass L4, light Door screen, the 5th eyeglass L5 and the 6th eyeglass L6, in which: the second eyeglass L2, third eyeglass L3 and the 6th eyeglass L6 have positive light coke, 4th eyeglass L4 has negative power, and the 5th eyeglass L5 integrally has positive light coke and is cemented doublet.

The 6th eyeglass L6 is aspherical lens.

The first eyeglass group G1 and the second eyeglass group G2 meets: 2.5 < F_G1/F_G2< 3.5, in which: F_G1For the first eyeglass The whole focal length of group G1, F_G2For the whole focal length of the second eyeglass group G2.

The camera lens of the first eyeglass group G1 and the second eyeglass group G2 composition meets following relationship: 0.3 < BFL/EFL < 0.7, in which: BFL is the optic back focal of camera lens, and EFL is the whole focal length of camera lens.

The 6th eyeglass L6 meets: N_D6> 1.75, in which: N_D6For the 6th eyeglass L6 relative to d line (λ= 587.5600nm) refractive index.

The diaphragm preferably satisfies at a distance from the eyeglass of front and back: -1.5 < L1-L2 < 1.5, in which: L1 is diaphragm to preceding mirror The distance at piece center, L2 are distance of the diaphragm to rear lens center.Pass through the difference of the distance of snoot to front and back center of lens Value, so that camera lens object distance, during infinitely change as far as short distance, the variation of the field angle of camera lens is small.

The EFL=85.0 of the present embodiment 1, camera lens calculate the f-number TNO=1.50 after transmitance, the structure ginseng of each eyeglass As shown in table 1, imaging parameters are as shown in Figures 2 and 3 for number.

1 lens construction parameter of table

Mirror surface serial number	Mirror types	Radius of curvature	Thickness	Refractive index	Abbe number
						Object plane			D0
S1	Spherical surface	73.21	10.38	1.50	70.3
						S2	Spherical surface	INF	3.0	1.72	23.5
S3	Spherical surface	165.11	D1
						S4	Spherical surface	72.05	7.03	1.82	43.2
S5	Spherical surface	232.0	0.2
						S6	Spherical surface	33.79	7.21	1.80	46.5
S7	Spherical surface	42.74	2.9
						S8	Spherical surface	66.02	3.4	1.60	65
S9	Spherical surface	23.85	9.62
						Diaphragm	Plane	INF	8.43
S11	Spherical surface	-26.749	3.1	1.72	54
						S12	Spherical surface	239.67	8.62	1.82	40
S13	Spherical surface	-41.82	0.33
						S14	It is aspherical	183.23	10.36	1.80	46.3
S15	It is aspherical	-72.26	40.01
						Image planes			-

Table 2

	POS1	POS2
			D0	INF	750
D1	12.67	1.75
			FOV	29.28	28.54

From D0 to D1 change process, as object distance from it is infinite as far as nearest photo distance change process.FOV is camera lens Field angle, from D0 to D1 change when, FOV has only changed 2.5%, and cell breath is faint.

The asphericity coefficient of the 6th eyeglass L6 is as shown in table 3.

3 camera lens asphericity coefficient of table

Wherein: K is circular cone coefficient, and e is scientific count number, such as e-005 indicates 10^-5。

Embodiment 2

First eyeglass group G1 described in the present embodiment is the first front lens L1 with positive light coke and has negative light focus The first rear lens L2 composition of degree.

Whole focal length EFL=85.0, the TNO=1.50 of camera lens in the present embodiment, the structural parameters of each eyeglass such as 4 institute of table Show, lens construction is as shown in figure 4, imaging parameters are as shown in Figure 5 and Figure 6.

4 lens construction parameter of table

Mirror surface serial number	Mirror types	Radius of curvature	Thickness	Refractive index	Abbe number
						Object plane			D0
S1	Spherical surface	79.24	9.25	1.71	54
						S2	Spherical surface	905.49	0.50
S3	Spherical surface	426.31	3.62	1.72	28.5
						S4	Spherical surface	128.03	D1
S5	Spherical surface	60.22	7.18	1.80	45.2
						S6	Spherical surface	120.91	0.20
S7	Spherical surface	33.93	7.10	1.78	46.5
						S8	Spherical surface	41.55	3.20
S9	Spherical surface	56.15	3.60	1.72	28.3
						S10	Spherical surface	22.52	9.25
Diaphragm	Plane	INF	8.33
						S12	Spherical surface	-30.37	4.78	1.72	28.3
S13	Spherical surface	131.02	10.01	1.82	40
						S14	Spherical surface	-47.16	0.20
S15	It is aspherical	130.45	9.61	1.80	46.3
						S16	It is aspherical	-94.17	39.43
Image planes			-

Table 5

	POS1	POS2
			D0	INF	750
D1	10.85	1.83
			FOV	28.94	28.20

From D0 to D1 change process, as object distance from it is infinite as far as nearest photo distance change process.FOV is camera lens Field angle, from D0 to variation when, FOV has only changed 2.6%, and cell breath is faint.

The asphericity coefficient of the 6th eyeglass L7 in the present embodiment is as shown in table 6.

6 camera lens asphericity coefficient of table

Wherein: K is circular cone coefficient, and e is scientific count number, such as e-005 indicates 10^-5。

Above-mentioned specific implementation can by those skilled in the art under the premise of without departing substantially from the principle of the invention and objective with difference Mode carry out local directed complete set to it, protection scope of the present invention is subject to claims and not by above-mentioned specific implementation institute Limit, each implementation within its scope is by the constraint of the present invention.

Claims (4)

1. interchangeable of dolly-out,ing dolly-back in one kind tight shot characterized by comprising the first mirror being arranged successively from the object side to image side Piece group and the second eyeglass group, in which: when shooting object from infinity to when short distance movement, the first eyeglass group is fixed, the Two eyeglass groups are focused from image side to the movement of object side；

The first eyeglass group are as follows:

The whole cemented doublet with positive light coke, i.e., by the first front lens towards object space and the first rear lens towards image space Composition, or

By two independent eyeglasses with positive light coke and negative power, i.e. the first front lens and the first rear lens composition；

The second eyeglass group include: the second eyeglass being arranged successively, third eyeglass, the 4th eyeglass, diaphragm, the 5th eyeglass and 6th eyeglass, in which: the second eyeglass, third eyeglass and the 6th eyeglass have positive light coke, and the 4th eyeglass has negative power, the The cemented doublet that five eyeglasses integrally have positive light coke and form for the 5th front lens and the 5th rear lens；

6th eyeglass is aspherical lens；

6th eyeglass meets: N_D6> 1.75, in which: N_D6Refractive index for the 6th eyeglass relative to d line；

The diaphragm meets at a distance from the eyeglass of front and back: -1.5 < L₁-L₂< 1.5, in which: L₁It is diaphragm into front lens The distance of the heart, L₂For diaphragm to the distance at rear lens center；

The first eyeglass group and the second eyeglass group meet: 2.5 < F_G1/F_G2< 3.5, in which: F_G1For the entirety of the first eyeglass group Focal length, F_G2For the whole focal length of the second eyeglass group；

The camera lens of the first eyeglass group and the second eyeglass group composition meets following relationship: 0.3 < BFL/EFL < 0.7, In: BFL is the optic back focal of camera lens, and EFL is the whole focal length of camera lens；

The first eyeglass group meets: 2 < F_G1/ F < 12, in which: F_G1For the focal length of the camera lens the first eyeglass group, F is should Camera lens whole focal length.

2. interchangeable of dolly-out,ing dolly-back according to claim 1 tight shot, characterized in that the 5th eyeglass meets: 0.2 <|N_D51 - N_D52| < 0.5, in which: N_D51It is the 5th eyeglass with positive light coke close to the refractive index of object space side mirror piece, N_D52It is the 5th eyeglass with positive light coke close to the refractive index of image side eyeglass.

3. interchangeable of dolly-out,ing dolly-back according to claim 1 tight shot, characterized in that when the first eyeglass group is When cemented doublet:

First mirror surface S1 of first front lens is spherical surface, radius of curvature 73.21559, the thickness of the first front lens It is 10.38, refractive index 1.5, Abbe number 70.3；

First mirror surface S2 of first rear lens is spherical surface, the first rear lens with a thickness of 3, refractive index 1.72, Abbe number is 23.5；

Second mirror surface S3 of first rear lens be spherical surface, radius of curvature 165.1134, the second of the first rear lens Mirror surface to the second eyeglass the first mirror surface with a thickness of 12.67；

First mirror surface S4 of second eyeglass be spherical surface, radius of curvature 72.05223, the second eyeglass with a thickness of 7.03, refractive index 1.82, Abbe number 43.2；

Second mirror surface S5 of second eyeglass is spherical surface, radius of curvature 232.0946, the second mirror surface of the second eyeglass To third eyeglass the first mirror surface with a thickness of 0.2；

First mirror surface S6 of the third eyeglass be spherical surface, radius of curvature 33.79069, third eyeglass with a thickness of 7.21, refractive index 1.8, Abbe number 46.5；

Second mirror surface S7 of the third eyeglass is spherical surface, radius of curvature 42.74051, the second mirror surface of third eyeglass To the 4th eyeglass the first mirror surface with a thickness of 2.9；

First mirror surface S8 of the 4th eyeglass be spherical surface, radius of curvature 66.02871, the 4th eyeglass with a thickness of 3.4, refractive index 1.6, Abbe number 65；

Second mirror surface S9 of the 4th eyeglass is spherical surface, radius of curvature 23.85449, the second mirror surface of the 4th eyeglass To diaphragm with a thickness of 9.62；

The diaphragm be plane, the first mirror surface of diaphragm to the 5th front lens with a thickness of 8.43；

First mirror surface S11 of the 5th front lens is spherical surface, and radius of curvature is -26.7493, the thickness of the 5th front lens It is 3.1, refractive index 1.72, Abbe number 54；

First mirror surface S12 of the 5th rear lens is spherical surface, radius of curvature 239.6707, the thickness of the 5th rear lens It is 8.62, refractive index 1.82, Abbe number 40；

Second mirror surface S13 of the 5th rear lens is spherical surface, and radius of curvature is -41.8223, the second of the 5th rear lens Mirror surface to the 6th eyeglass the first mirror surface with a thickness of 0.33；

First mirror surface S14 of the 6th eyeglass be aspherical, radius of curvature 183.2353, the 6th eyeglass with a thickness of 10.36, refractive index 1.8, Abbe number 46.3；

Second mirror surface S15 of the 6th eyeglass be it is aspherical, radius of curvature be -72.2656, the second mirror of the 6th eyeglass Face is to imaging surface with a thickness of 40.01；

The circular cone coefficient K of first mirror surface S14 of the 6th eyeglass is 0, camera lens asphericity coefficient are as follows: A (4th) is 3.16E- 05, B (6th) is -1.03E-07, C (8th) is that 1.30E-06, D (10th) are -5.14E-04；

The circular cone coefficient K of second mirror surface S15 of the 6th eyeglass is 0, camera lens asphericity coefficient are as follows: A (4th) is 5.96E- 04, B (6th) be 1.16E-05, C (8th) be -1.88E-08, D (10th) is -3.06E-13.

4. interchangeable of dolly-out,ing dolly-back according to claim 1 tight shot, characterized in that when the first eyeglass group by When individual first front lens and the first rear lens form:

First mirror surface S1 of first front lens be spherical surface, radius of curvature 79.24, the first front lens with a thickness of 9.25, refractive index 1.71, Abbe number 54；

Second mirror surface S2 of first front lens is spherical surface, radius of curvature 905.49, the second mirror of the first front lens Face to the first rear lens the first mirror surface with a thickness of 0.5；

First mirror surface S3 of first rear lens be spherical surface, radius of curvature 426.31, the first rear lens with a thickness of 3.62, refractive index 1.72, Abbe number 28.5；

Second mirror surface S4 of first rear lens is spherical surface, radius of curvature 128.03, the second mirror of the first rear lens Face to the second eyeglass the first mirror surface with a thickness of D1；

First mirror surface S5 of second eyeglass is spherical surface, radius of curvature 60.22, the second eyeglass with a thickness of 7.18, Its refractive index is 1.8, Abbe number 45.2；

Second mirror surface S6 of second eyeglass is spherical surface, and radius of curvature 120.91, the second mirror surface of the second eyeglass is extremely First mirror surface of third eyeglass with a thickness of 0.2；

First mirror surface S7 of the third eyeglass is spherical surface, radius of curvature 33.93, third eyeglass with a thickness of 7.1, Refractive index is 1.78, Abbe number 46.5；

Second mirror surface S8 of the third eyeglass is spherical surface, radius of curvature 41.55, the second mirror surface of third eyeglass to the First mirror surface of four eyeglasses is with a thickness of 3.2；

First mirror surface S9 of the 4th eyeglass is spherical surface, radius of curvature 56.15, the 4th eyeglass with a thickness of 3.6, Refractive index is 1.72, Abbe number 28.3；

Second mirror surface S10 of the 4th eyeglass is spherical surface, and radius of curvature 22.52, the second mirror surface of the 4th eyeglass is extremely Diaphragm with a thickness of 9.25；

The diaphragm be plane, the first mirror surface of diaphragm to the 5th front lens with a thickness of 8.33；

First mirror surface S12 of the 5th front lens be spherical surface, radius of curvature be -30.37, the 5th front lens with a thickness of 4.78, refractive index 1.72, Abbe number 28.3；

First mirror surface S13 of the 5th rear lens be spherical surface, radius of curvature 131.02, the 5th rear lens with a thickness of 10.01, refractive index 1.82, Abbe number 40；

Second mirror surface S14 of the 5th rear lens is spherical surface, and radius of curvature is -47.16, the second mirror of the 5th rear lens Face to the 6th eyeglass the first mirror surface with a thickness of 0.2；

First mirror surface S15 of the 6th eyeglass be aspherical, radius of curvature 130.45, the 6th eyeglass with a thickness of 9.61, refractive index 1.8, Abbe number 46.3；

Second mirror surface S16 of the 6th eyeglass be it is aspherical, radius of curvature be -94.17, the second mirror surface of the 6th eyeglass To imaging surface with a thickness of 39.43；

The circular cone coefficient K of first mirror surface S15 of the 6th eyeglass is 0, camera lens asphericity coefficient are as follows: A (4th) is 2.07E- 07, B (6th) is -2.36E-06, C (8th) is that 7.52E-07, D (10th) are -3.16E-05；

The circular cone coefficient K of second mirror surface S16 of the 6th eyeglass is 0, camera lens asphericity coefficient are as follows: A (4th) is 4.83E- 05, B (6th) be 3.27E-06, C (8th) be -2.13E-07, D (10th) is -5.34E-13.