阅读说明：本技术 显微镜物镜 (Microscope objective ) 是由 张雷梦婷 李伸朋 孙长胜 于 2021-07-05 设计创作，主要内容包括：本发明涉及一种显微镜物镜,包括沿光轴从物侧至像侧依次排列的光焦度为正的第一透镜群(T1)、光焦度为正的第二透镜群(T2)和光焦度为负的第三透镜群(T3),所述第一透镜群(T1)包含至少一枚胶合镜组。本发明的显微镜物镜具有物方视场大以及数值孔径大的优点。(The invention relates to a microscope objective lens, which comprises a first lens group (T1) with positive focal power, a second lens group (T2) with positive focal power and a third lens group (T3) with negative focal power, which are sequentially arranged from an object side to an image side along an optical axis, wherein the first lens group (T1) comprises at least one cemented lens group. The microscope objective lens has the advantages of large object space field and large numerical aperture.)

1. A microscope objective lens comprises a first lens group (T1) with positive focal power, a second lens group (T2) with positive focal power and a third lens group (T3) with negative focal power, which are arranged in sequence from an object side to an image side along an optical axis, wherein the first lens group (T1) comprises at least one cemented lens group.

2. The microscope objective according to claim 1, characterized in that the first lens group (T1) consists of a first optical element (G1) and a second optical element (G2);

the second lens group (T2) is composed of a third cemented lens group (G3), a fourth optical element (G4) and a fifth cemented lens group (G5);

the third lens group (T3) is composed of a sixth optical element (G6) and a seventh optical element (G7).

3. A microscope objective according to claim 2, characterized in that the first optical element (G1) is a double cemented lens with positive optical power;

the object side surface of the first optical element (G1) is a plane, and the image side surface of the first optical element is a hemispherical surface.

4. The microscope objective according to claim 3, characterized in that the first optical element (G1) consists of a plano-convex lens on the object side and a hyper-hemispherical lens on the image side.

5. The microscope objective according to claim 2, characterized in that the second optical element (G2) is a lens having a positive optical power;

the second optical element (G2) is in the shape of a meniscus with a concave object side.

6. A microscope objective according to claim 2, characterized in that the third cemented lens group (G3) consists of two lenses of positive power and one lens of negative power;

the two lenses with positive focal power are made of low-dispersion materials.

7. A microscope objective according to claim 2, characterized in that the fourth optical element (G4), when it is a double cemented lens set, consists of a lens of positive power and a lens of negative power.

8. A microscope objective according to claim 2, characterized in that the fifth cemented lens group (G5) consists of a lens of positive power and a lens of negative power.

9. The microscope objective according to claim 2, characterized in that the optical powers of the sixth optical element (G6) and the seventh optical element (G7) differ positively or negatively and form a symmetrical double Gaussian structure.

10. A microscope objective according to claim 2, characterized in that the sixth optical element (G6) consists of a lens of positive power and a lens of negative power;

the seventh optical element (G7) is composed of a negative power lens on the object side and a positive power lens on the image side.

Technical Field

The invention relates to the field of microscopes, in particular to a microscope objective.

Background

Due to the increasing demands of life sciences and industrial fields for observation resolution and imaging speed, the demands for microscope objectives with larger field of view and larger aperture (NA) are increasing. Therefore, in order to improve the performance and market competitiveness of microscope objectives, a large field of view and a large numerical aperture are becoming the development trend of microscope objectives. Certainly, when apochromatism of large field of view and large numerical aperture is realized, the structure of the microscope objective lens is required to be ensured to have better processability, so that the method plays an important role in the production of the microscope objective lens with large field of view and large numerical aperture. However, in the prior art, a 100X oil-scope is usually used for observing a sample, and the numerical aperture of the objective is 1.35, and the object space field of view is 0.265mm, so that the requirements of large-market and large-numerical-value holes are far from being met.

Disclosure of Invention

The invention aims to provide a microscope objective.

In order to achieve the above object, the present invention provides a microscope objective lens, which includes a first lens group having a positive optical power, a second lens group having a positive optical power, and a third lens group having a negative optical power, which are arranged in order from an object side to an image side along an optical axis, wherein the first lens group includes at least one cemented lens group.

According to an aspect of the present invention, the first lens group is composed of a first optical element and a second optical element;

the second lens group consists of a third cemented lens group, a fourth optical element and a fifth cemented lens group;

the third lens group is composed of a sixth optical element and a seventh optical element.

According to one aspect of the present invention, the first optical element is a double cemented lens having a positive focal power;

the object side surface of the first optical element is a plane, and the image side surface of the first optical element is a hemispherical surface.

According to an aspect of the present invention, the first optical element is composed of a plano-convex lens on an object side and a hyper-hemispherical lens on an image side.

According to one aspect of the invention, the second optical element is a lens having a positive optical power;

the second optical element is in a meniscus shape with a concave object side surface.

According to one aspect of the present invention, the third cemented lens group consists of two lenses with positive focal power and one lens with negative focal power;

the two lenses with positive focal power are made of low-dispersion materials.

According to an aspect of the invention, when the fourth optical element is a double cemented lens, the fourth optical element is composed of a lens with positive focal power and a lens with negative focal power.

According to one aspect of the present invention, the fifth cemented lens group is composed of a positive focal power lens and a negative focal power lens.

According to one aspect of the invention, the sixth optical element and the seventh optical element have powers that are different in a positive or negative polarity and form a symmetrical double-gauss structure.

According to one aspect of the invention, the sixth optical element is composed of a lens with positive focal power and a lens with negative focal power;

the seventh optical element is composed of a negative power lens on the object side and a positive power lens on the image side.

According to one aspect of the invention, the distance D from the object plane to the rearmost surface of the microscope objective and the focal length fobj of the microscope objective satisfy the following relationship: 10< D/fobj < 36.2;

the focal length fobj of the microscope objective satisfies the following condition: fobj > 1.7;

the objective numerical aperture NA of the microscope objective meets the following conditions: NA is more than 1 and less than or equal to 1.45.

According to an aspect of the present invention, the highest projection height H2 of the central field edge rays in the second lens group, the lowest projection height H1 of the central field edge rays in the third lens group on the lens surface, and the projection height H3 of the central field edge rays on the first lens surface of the second lens group satisfy the following relations: 0.5< | H2/H3| < 1.5; 0.1< | H1/H2| < 0.8.

According to an aspect of the present invention, the focal length fL1 and the object-side radius RL1 of the first cemented lens of the first lens group and the focal length fobj of the microscope objective lens satisfy the following relationships, respectively: 1< | fL1/fobj |; l RL1/fobj | ═ infinity.

According to an aspect of the invention, the combined focal length fT1 of the first lens group and the focal length fobj of the microscope objective lens satisfy the following relation 1< | fT1/fobj | < 5.

According to an aspect of the invention, the combined focal length fT2 of the second lens group and the focal length fobj of the microscope objective lens satisfy the following relationship: 1< | fT2/fobj | < 25.

According to an aspect of the invention, the combined focal length fT3 of the third lens group and the focal length fobj of the microscope objective lens satisfy the following relationship: 1< | fT3/fobj |.

According to one aspect of the invention, for bright field observation, the number of fields of view is at most 35, and a wavelength band of 436-.

According to one aspect of the invention, the first lens group comprises a plano-convex lens and a meniscus lens, the group serving to rapidly elevate most of the numerical aperture and to bear pressure on the following lens group to elevate the numerical aperture angle.

According to one aspect of the present invention, the second lens group comprises a triple cemented lens group, a single lens or double cemented lens group and a double cemented lens group. The role of this group is mainly to correct/eliminate chromatic aberrations.

According to one aspect of the present invention, the third lens group is formed by a positive optical element, a negative optical element, and a double-gauss structure, and the function of the group is mainly to correct curvature of field and increase the field of view.

Drawings

FIG. 1 schematically shows a configuration of a microscope objective lens according to a first embodiment of the present invention;

FIG. 2 schematically shows a 0-field transverse aberration diagram of a microscope objective lens according to a first embodiment of the invention;

FIG. 3 schematically shows a 1-field transverse aberration diagram of a microscope objective lens according to a first embodiment of the invention;

FIG. 4 is a field curvature distortion plot schematically illustrating a microscope objective lens according to a first embodiment of the present invention;

FIG. 5 schematically shows a chromatic aberration diagram of a microscope objective according to a first embodiment of the invention;

FIG. 6 is a schematic diagram showing the structure of a microscope objective lens according to a second embodiment of the present invention;

FIG. 7 schematically shows a 0-field transverse aberration diagram of a microscope objective lens according to a second embodiment of the invention;

FIG. 8 schematically shows a 1-field transverse aberration diagram of a microscope objective lens according to a second embodiment of the invention;

FIG. 9 is a field curvature distortion plot schematically illustrating a microscope objective lens according to a second embodiment of the present invention;

FIG. 10 schematically shows a chromatic aberration diagram of a microscope objective according to a second embodiment of the invention;

FIG. 11 is a schematic representation of the construction of a microscope objective lens according to a third embodiment of the invention;

FIG. 12 schematically shows a 0-field transverse aberration diagram of a microscope objective lens according to a third embodiment of the invention;

FIG. 13 schematically shows a 1-field transverse aberration diagram of a microscope objective lens according to a third embodiment of the invention;

FIG. 14 schematically shows a field curvature distortion diagram of a microscope objective lens according to a third embodiment of the present invention;

FIG. 15 shows schematically a chromatic aberration diagram of a microscope objective according to a third embodiment of the invention;

FIG. 16 is a schematic diagram showing the construction of a microscope objective lens according to a fourth embodiment of the present invention;

FIG. 17 schematically shows a 0-field transverse aberration diagram of a microscope objective lens according to a fourth embodiment of the invention;

FIG. 18 schematically shows a 1-field transverse aberration diagram of a microscope objective lens according to a fourth embodiment of the invention;

FIG. 19 schematically shows a field curvature distortion diagram of a microscope objective lens according to a fourth embodiment of the present invention;

FIG. 20 shows schematically a chromatic aberration diagram of a microscope objective according to a fourth embodiment of the invention;

FIG. 21 is a schematic diagram showing the configuration of a microscope objective lens according to a fifth embodiment of the present invention;

FIG. 22 is a diagram schematically illustrating the transverse aberration of the 0 field of view of a microscope objective lens according to a fifth embodiment of the present invention;

FIG. 23 schematically shows a 1-field transverse aberration diagram of a microscope objective lens according to a fifth embodiment of the invention;

FIG. 24 is a field curvature distortion plot schematically illustrating a microscope objective lens according to a fifth embodiment of the present invention;

fig. 25 schematically shows a chromatic aberration diagram of a microscope objective lens according to a fifth embodiment of the present invention.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

In describing embodiments of the present invention, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship that is based on the orientation or positional relationship shown in the associated drawings, which is for convenience and simplicity of description only, and does not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus, the above-described terms should not be construed as limiting the present invention.

The present invention is described in detail below with reference to the drawings and the specific embodiments, which are not repeated herein, but the embodiments of the present invention are not limited to the following embodiments.

Referring to fig. 1, the microscope objective of the present invention belongs to an infinite conjugate objective, and during observation, a medium between an observation object and the microscope objective may be air or liquid. When the medium is air, the numerical aperture is less than 1, and when the medium is liquid, the numerical aperture can reach the maximum value. The microscope objective lens includes a first optical element G1, a second optical element G2, a third cemented lens group G3, a fourth optical element G4, a fifth cemented lens group G5, a sixth optical element G6, and a seventh optical element G7, which are arranged in order from the object side to the image side along the optical axis. In the present invention, the fourth optical element G4 is a lens or a double cemented lens. Of course, in some embodiments where the fourth optical element G4 is a lens, it can be replaced by a double cemented lens set.

In the present invention, the first optical element G1 is a double-lens assembly with positive focal power, and has a planar object-side surface and a hemispherical (or nearly hemispherical) image-side surface. Specifically, the first optical element G1 is composed of a plano-convex lens on the object side and a hyper-hemispherical lens on the image side. The second optical element G2 is a lens or a cemented lens group having positive optical power and a meniscus or biconvex shape with a concave object-side surface. The third cemented lens group G3 is composed of two lenses with positive refractive power and one lens with negative refractive power, wherein the two lenses with positive refractive power are made of low dispersion material. When the fourth optical element G4 is a double cemented lens, it is composed of a positive focal power lens and a negative focal power lens. The fifth cemented lens group G5 is composed of a positive focal power lens and a negative focal power lens. The sixth optical element G6 and the seventh optical element G7 have powers that are different between positive and negative (i.e., one positive and one negative), and form a double gauss structure, e.g., in some embodiments, the sixth optical element G6 has negative power and the seventh optical element G7 has positive power. The sixth optical element G6 and the seventh optical element G7 can be a lens, a cemented lens group, or a combination of a lens and a cemented lens group. Specifically, the sixth optical element G6 may be composed of a lens with positive focal power and a lens with negative focal power; the seventh optical element G7 may be composed of a negative power lens on the object side and a positive power lens on the image side. In addition, the powers of the fifth cemented lens group G5 and the sixth optical element G6 may also be changed accordingly.

In the present invention, the focal power of the first lens group T1 composed of the first optical element G1 and the second optical element G2 is positive, and as can be seen from the above description, the first lens group T1 includes at least one lens with positive focal power, and may be composed of one double cemented lens set and one or more single lenses. The focal power of the second lens group T2 composed of the third cemented lens group G3, the fourth optical element G4 and the fifth cemented lens group G5 is positive, and as can be seen from the above, the second lens group T2 is composed of at least one optical element, and may be a single lens or a cemented lens group, and the cemented lens group refers to a double-cemented lens or a multi-lens cemented lens. The third lens group T3 composed of the sixth optical element G6 and the seventh optical element G7 has negative optical power.

In the invention, the distance D from the object plane to the last surface of the microscope objective lens and the focal length fobj of the microscope objective lens satisfy the following relation: 10< D/fobj < 36.2. The focal length fobj of the microscope objective satisfies the following condition: fobj > 1.7. The numerical aperture NA of the object space of the microscope objective lens meets the following conditions: NA is more than 1 and less than or equal to 1.45.

In the invention, the highest projection height H2 of the central field edge light in the second lens group T2, the lowest projection height H1 of the central field edge light in the third lens group T3 on the lens surface, and the projection height H3 of the central field edge light on the first lens surface of the second lens group T2 respectively satisfy the following relations: 0.5< | H2/H3| < 1.5; 0.1< | H1/H2| < 0.8. The light height reaches a maximum value between the first lens surface and the last lens surface of the second lens group T2.

In the invention, the focal length fL1 and the radius value RL1 of the object side surface of the first cemented lens of the first lens group T1 respectively satisfy the following relations with the focal length fobj of the microscope objective lens: 1< | fL1/fobj |; l RL1/fobj | ═ infinity.

In the present invention, the combined focal length fT1 of the first lens group T1 and the focal length fobj of the microscope objective lens satisfy the following relationship 1< | fT1/fobj | < 5. The combined focal length fT2 of the second lens group T2 and the focal length fobj of the microscope objective lens satisfy the following relationship: 1< | fT2/fobj | < 25. The combined focal length fT3 of the third lens group T3 and the focal length fobj of the microscope objective lens satisfy the following relationship: 1< | fT3/fobj |.

In summary, the microscope objective lens of the present invention integrally includes three lens groups, and the first lens group T1 is composed of a double cemented lens group and one or more single lenses, and is used to increase the objective numerical aperture. The second lens group T2 is composed of at least one cemented lens group and a single lens, and is used for eliminating chromatic aberration. The third lens group T3 is composed of a double-gauss structure for achieving the effects of flat field and increased field of view. Therefore, the microscope objective lens meets the setting, the maximum field of view number of the microscope objective lens can reach 35, the maximum numerical aperture can reach 1.4, and the maximum field of view can reach 0.625 mm. Moreover, the working distance of the microscope objective can reach more than 0.15mm, certainly, the working distance also comprises the working distance between 0mm and 0.15mm, and the working distance is the distance from the cover glass to the edge of the first group of lenses of the objective. The number of the lenses is the highest cost performance of 13-14 lenses, the lens can be applied to bright field observation, the maximum number of fields of view can reach 35, and the maximum numerical aperture can reach 1.4. The use of a wavelength band (436-. Of course, lenses may be added to further improve performance.

The microscope objective lens of the present invention will be specifically described below in five embodiments, where the surfaces of the respective lenses are denoted by S1, S2, …, and SN, and the cemented surface in the cemented lens group is referred to as one surface. In the following embodiments, the first lens group T1 is mainly responsible for providing optical power and reducing the numerical aperture of the posterior portion, the second lens group T2 is mainly used for correcting chromatic aberration, and the third lens group T3 is mainly used for correcting curvature of field and increasing the field of view. In some embodiments, the working waveband of the microscope objective can be 436nm-1000nm, the apochromatic effect in the spectrum waveband interval of 436-.

The parameters of each embodiment specifically satisfying the above relationship are shown in table 1 below:

TABLE 1

First embodiment

Referring to fig. 1, in the present embodiment, the microscope objective lens has 14 lenses in total, the first lens surface from the object side is S1, and the last lens surface is S21.

The first optical element G1 is a cemented lens group with positive focal power and plano-convex shape, the first lens L1 close to the object side is a plano-convex lens, and the second lens L2 away from the object side is a hyper-hemispherical lens; the second optical element G2 is a lens, i.e., the third lens L3, the focal power is positive, the shape is meniscus, and the object side surface is concave; the third cemented lens group G3 consists of two positive focal power lenses and a negative focal power lens, namely a fourth lens L4, a fifth lens L5 and a sixth lens L6, wherein the two positive focal power lenses can be made of the same or different materials and are low-dispersion materials; the fourth optical element G4 is a double-cemented lens assembly, and the focal power of the seventh lens element L7 on the object side is positive and the focal power of the eighth lens element L8 on the image side is negative; in the fifth cemented lens group G5, the power of the ninth lens element L9 on the object side is positive, and the power of the tenth lens element L10 on the image side is negative; the sixth optical element G6 is a double-cemented lens assembly, and the focal power of the eleventh lens L11 on the object side is negative, and the focal power of the twelfth lens L12 on the image side is positive; the seventh optical element G7 is a double-cemented lens assembly, and the power of the thirteenth lens element L13 on the object side is negative and the power of the fourteenth lens element on the image side is positive. The sixth optical element G6 and the seventh optical element G7 form two symmetrical double-glue combinations, i.e., form a double-gaussian structure.

In this embodiment, the focal length of the system is 3mm, the working distance is 0.15mm, the numerical aperture is 1.35, and the parameters of the microscope objective lens, such as the lens thickness and radius, are shown in table 2 below:

TABLE 2

Where radius refers to the radius of curvature of a surface and thickness refers to the on-axis distance from the current surface to the next surface, e.g., the thickness of surface S1 is the distance from S1 to S2, which may be the on-axis thickness of the medium or lens, or the on-axis air gap between them.

Fig. 2 is a transverse aberration diagram of the 0 field of view of the microscope objective lens according to the first embodiment, in which abscissa PY and PX represent normalized entrance pupil size, ordinate represents transverse aberration, scale is ± 5 μm, Y direction is a meridional direction, and X direction is a sagittal direction.

FIG. 3 is a 1-field transverse aberration diagram of the microscope objective lens of the first embodiment, wherein the scale is + -5 μm, and the curve is close to the horizontal axis, so that the microscope objective lens has better imaging performance.

Fig. 4 is a field curvature distortion diagram of the microscope objective lens of the first embodiment, the left diagram being a field curvature diagram in which the ordinate represents the field of view and the abscissa represents the field curvature in μm. The axial difference between the optimal focus point of the edge view field and the optimal focus point of the central view field is less than 2 lambda/NA²The theoretical value meets the requirement of clear full-field and flat-field objective lens. The ordinate in the figure is the normalized field of view; the abscissa represents the field curvature with a maximum value of 5 μm and a minimum value of-5 μm. The distortion graph is shown on the right, wherein the ordinate represents the field of view and the abscissa represents the distortion (percentage), and the distortion of the full field of view is less than 2%. In the figure, the ordinate is the normalized field of view and the abscissa represents the distortion, maximum 2%, minimum-2%.

FIG. 5 is a graph showing the chromatic aberration of the objective lens of the microscope according to the first embodiment, wherein the chromatic aberration of the full-wavelength curve is better corrected, and the difference between any two curves at each field is smaller than lambda/NA²。

The large-field-of-view flat-field immersion microscope objective lens of the present embodiment has a large object field (0.5mm), a large numerical aperture (NA ═ 1.35), a field of view that can be greater than 0.58mm, and in some preferred embodiments, a numerical aperture that can be greater than 1.4.

Second embodiment

Referring to fig. 6, in the present embodiment, the microscope objective lens has 13 lenses in total, the first lens surface from the object side is S1, and the last lens surface is S20.

The first optical element G1 is a cemented lens group with positive focal power and plano-convex shape, the first lens L1 close to the object side is a plano-convex lens, and the second lens L2 away from the object side is a hyper-hemispherical lens; the second optical element G2 is a lens, i.e., the third lens L3, the focal power is positive, the shape is meniscus, and the object side surface is concave; a third cemented lens group G3, which is composed of two positive power lenses and one negative power lens, and is a fourth lens L4, a fifth lens L5 and a sixth lens L6 respectively; the two positive focal power lens materials can be the same or different and are low dispersion materials; the fourth optical element G4 is a single lens, i.e., a seventh lens L7; in the fifth cemented lens group G5, the power of the eighth lens element L8 on the object side is negative, and the power of the ninth lens element L9 on the image side is positive; the sixth optical element G6 is a double-cemented lens assembly with negative refractive power, the tenth lens element L10 on the object side has positive refractive power, and the eleventh lens element L11 on the image side has negative refractive power; the seventh optical element G7 is a double-lens assembly with positive optical power, the power of the twelfth lens element L12 on the object side is negative, and the power of the thirteenth lens element L13 on the image side is positive. The sixth optical element G6 and the seventh optical element G7 form two symmetrical double-glue combinations, i.e., form a double-gaussian structure.

In this embodiment, the focal length of the system is 3mm, the working distance is 0.15mm, the numerical aperture is 1.4, and the parameters of the microscope objective lens, such as the lens thickness and radius, are shown in table 3 below:

surface of	Radius (mm)	Thickness (mm)	Nd	Vd
					S20	5.637	3.3	1.85	23.8
S19	9.875	1	1.61	45.2
					S18	3.527	2.8
S17	-3.757	2.5	1.88	40.8
					S16	90.853	5	1.60	83.4
S15	-6.735	0.15
					S14	-80.256	5.5	1.43	95
S13	-8.651	1.5	1.61	45.2
					S12	-24.587	0.15
S11	37.886	3	1.43	95
					S10	-37.886	0.15
S9	17.695	6	1.43	95
					S8	-13.587	1.2	1.61	44.3
S7	13.587	7.35	1.43	95
					S6	-16.178	0.15
S5	7.958	3.9	1.43	95
					S4	18.663	0.15
S3	4.268	5	1.88	40.8
					S2	2.324	0.5	1.52	32.2
S1	Infinity	0.15

TABLE 3

Where radius refers to the radius of curvature of a surface and thickness refers to the on-axis distance from the current surface to the next surface, e.g., the thickness of surface S1 is the distance from S1 to S2, which may be the on-axis thickness of the medium or lens, or the on-axis air gap between them.

Fig. 7 is a transverse aberration diagram of the 0 field of view of the microscope objective lens according to the second embodiment, in which abscissa PY and PX represent normalized entrance pupil size, ordinate represents transverse aberration, scale is ± 5 μm, Y direction is a meridional direction, and X direction is a sagittal direction.

FIG. 8 is a transverse aberration diagram of the field of view 1 of the microscope objective lens according to the second embodiment, wherein the scale is + -5 μm, and the horizontal axis is close to the curve visible from the diagram, so that the microscope objective lens has better imaging performance.

Fig. 9 is a field curvature distortion diagram of the microscope objective lens of the second embodiment, the left diagram being a field curvature diagram in which the ordinate represents the field of view and the abscissa represents the field curvature in μm. The axial difference between the optimal focus point of the edge view field and the optimal focus point of the central view field is less than 2 lambda/NA²The theoretical value meets the requirement of clear full-field and flat-field objective lens. The ordinate in the figure is the normalized field of view; the abscissa represents the field curvature, with a maximum value of 5 μm and a minimum value of-5 μm. The distortion graph is shown on the right, wherein the ordinate represents the field of view and the abscissa represents the distortion (percentage), and the distortion of the full field of view is less than 2%. In the figure, the ordinate is the normalized field of view and the abscissa represents the distortion, maximum 2%, minimum-2%.

FIG. 10 is a graph showing the chromatic aberration of the objective lens of the microscope according to the second embodiment, in which the chromatic aberration of the full-wavelength curve is better corrected, and the difference between any two curves at each field is smaller than λ/NA²。

The large-field-of-view flat-field immersion microscope objective lens of the present embodiment has a large object field (0.5mm), a large numerical aperture (NA ═ 1.4), a field of view that can be greater than 0.58mm, and in some preferred embodiments, a numerical aperture that can be greater than 1.4.

Third embodiment

Referring to fig. 11, in the present embodiment, the microscope objective lens has 13 lenses in total, the first lens surface from the object side is S1, and the last lens surface is S20.

The first optical element G1 is a cemented lens group with positive focal power and plano-convex shape, the first lens L1 close to the object side is a plano-convex lens, and the second lens L2 away from the object side is a hyper-hemispherical lens; the second optical element G2 is a lens, i.e., the third lens L3, the focal power is positive, the shape is meniscus, and the object side surface is concave; a third cemented lens group G3, which is composed of two positive power lenses and one negative power lens, and is a fourth lens L4, a fifth lens L5 and a sixth lens L6 respectively; the two positive focal power lens materials can be the same or different and are low dispersion materials; the fourth optical element G4 is a single lens, i.e., a seventh lens L7; in the fifth cemented lens group G5, the power of the eighth lens element L8 on the object side is negative, and the power of the ninth lens element L9 on the image side is positive; the sixth optical element G6 is a double-cemented lens assembly, and the power of the tenth lens element L10 on the object side is positive and the power of the eleventh lens element L11 on the image side is negative; the seventh optical element G7 is a double-cemented lens assembly, and the power of the twelfth lens element L12 on the object side is negative, and the power of the thirteenth lens element L13 on the image side is positive. The sixth optical element G6 and the seventh optical element G7 form two symmetrical double-glue combinations, i.e., form a double-gaussian structure.

In this embodiment, the system focal length f is 1.8mm, the working distance is 0.15mm, the numerical aperture is 1.3, and the lens thickness and radius of the microscope objective lens are as shown in table 4 below:

TABLE 4

Where radius refers to the radius of curvature of a surface and thickness refers to the on-axis distance from the current surface to the next surface, e.g., the thickness of surface S1 is the distance from S1 to S2, which may be the on-axis thickness of the medium or lens, or the on-axis air gap between them.

Fig. 12 is a transverse aberration diagram of the 0 field of view of the microscope objective lens according to the third embodiment, in which abscissa PY and PX represent normalized entrance pupil size, ordinate represents transverse aberration, scale is ± 5 μm, Y direction is a meridional direction, and X direction is a sagittal direction.

FIG. 13 is a 1-field transverse aberration diagram of a microscope objective lens according to a third embodiment, wherein a scale is + -5 μm, and a graph with a visible curve close to a transverse axis has a good imaging performance.

Fig. 14 is a field curvature distortion diagram of a microscope objective lens of the third embodiment, the left diagram being a field curvature diagram in which the ordinate represents the field of view and the abscissa represents the field curvature in μm. The axial difference between the optimal focus point of the edge view field and the optimal focus point of the central view field is less than 2 lambda/NA²The theoretical value meets the requirement of clear full-field and flat-field objective lens. The ordinate in the figure is the normalized field of view; the abscissa represents the field curvature with a maximum value of 2 μm and a minimum value of-2 μm. The distortion graph is shown on the right, wherein the ordinate represents the field of view and the abscissa represents the distortion (percentage), and the distortion of the full field of view is less than 1%. The ordinate of the diagram is the normalized field of view, the abscissaThe coordinates represent the distortion, max 1%, min-1%.

FIG. 15 is a chromatic aberration curve chart of the microscope objective lens of the third embodiment, in which the chromatic aberration of the full-wavelength curve is corrected well, and the difference between any two curves at each field is smaller than λ/NA²。

The large-field-of-view flat-field immersion microscope objective lens of the present embodiment has a large object field (0.5mm), a large numerical aperture (NA ═ 1.3), a field of view that can be greater than 0.58mm, and in some preferred embodiments, a numerical aperture that can be greater than 1.4.

Fourth embodiment

Referring to fig. 16, in the present embodiment, the microscope objective lens has 14 lenses in total, the first lens surface from the object side is S1, and the last lens surface is S21.

The first optical element G1 is a cemented lens group with positive focal power and plano-convex shape, the first lens L1 close to the object side is a plano-convex lens, and the second lens L2 away from the object side is a hyper-hemispherical lens; the second optical element G2 is a lens, i.e., the third lens L3, the focal power is positive, the shape is meniscus, and the object side surface is concave; a third cemented lens group G3, which is composed of two positive power lenses and one negative power lens, and is a fourth lens L4, a fifth lens L5 and a sixth lens L6 respectively; the two positive focal power lens materials can be the same or different and are low dispersion materials; the fourth optical element G4 is a double-cemented lens assembly, and the focal power of the seventh lens element L7 on the object side is negative, and the focal power of the eighth lens element L8 on the image side is positive; in the fifth cemented lens group G5, the power of the ninth lens element L9 on the object side is negative, and the power of the tenth lens element L10 on the image side is positive; the sixth optical element G6 is a double-cemented lens assembly, and the focal power of the eleventh lens L11 on the object side is positive and the focal power of the twelfth lens L12 on the image side is negative; the seventh optical element G7 is a double-cemented lens assembly, and the power of the thirteenth lens element L13 on the object side is negative, and the power of the fourteenth lens element L14 on the image side is positive. The sixth optical element G6 and the seventh optical element G7 form two symmetrical double-glue combinations, i.e., form a double-gaussian structure.

In this embodiment, the system focal length f is 1.8mm, the working distance is 0.15mm, the numerical aperture is 1.36, and the parameters of the microscope objective lens, such as lens thickness and radius, are shown in table 5 below:

TABLE 5

Where radius refers to the radius of curvature of a surface and thickness refers to the on-axis distance from the current surface to the next surface, e.g., the thickness of surface S1 is the distance from S1 to S2, which may be the on-axis thickness of the medium or lens, or the on-axis air gap between them.

Fig. 17 is a transverse aberration diagram of the 0 field of view of the microscope objective lens according to the fourth embodiment, in which abscissa PY and PX represent normalized entrance pupil size, ordinate represents transverse aberration, scale is ± 5 μm, Y direction is a meridional direction, and X direction is a sagittal direction.

FIG. 18 is a 1-field transverse aberration diagram of a microscope objective lens according to a fourth embodiment, wherein a scale is + -5 μm, and a graph showing a curve close to a transverse axis has a good imaging performance.

Fig. 19 is a field curvature distortion diagram of a microscope objective lens of the fourth embodiment, the left diagram being a field curvature diagram in which the ordinate represents the field of view and the abscissa represents the field curvature in μm. The axial difference between the optimal focus point of the edge view field and the optimal focus point of the central view field is less than 2 lambda/NA²The theoretical value meets the requirement of clear full-field and flat-field objective lens. The ordinate in the figure is the normalized field of view; the abscissa represents the field curvature with a maximum value of 2 μm and a minimum value of-2 μm. The distortion graph is shown on the right, wherein the ordinate represents the field of view and the abscissa represents the distortion (percentage), and the distortion of the full field of view is less than 1%. In the figure, the ordinate is the normalized field of view and the abscissa represents the distortion, with a maximum of 1% and a minimum of-1%.

FIG. 20 is a graph showing the chromatic aberration of the objective lens of the microscope according to the fourth embodiment, in which the chromatic aberration of the full-wavelength curve is corrected well, and the difference between any two curves at each field is smaller than λ/NA²。

The large field-of-view, flat-field immersion microscope objective of this embodiment has a large numerical aperture (NA ═ 1.36), and in some preferred embodiments can have a numerical aperture greater than 1.4.

Fifth embodiment

Referring to fig. 21, in the present embodiment, the microscope objective lens has 14 lenses in total, the first lens surface from the object side is S1, and the last lens surface is S21.

The first optical element G1 is a cemented lens group with positive focal power and plano-convex shape, the first lens L1 close to the object side is a plano-convex lens, and the second lens L2 away from the object side is a hyper-hemispherical lens; the second optical element G2 is a lens, i.e., the third lens L3, the focal power is positive, the shape is meniscus, and the object side surface is concave; a third cemented lens group G3, which is composed of two positive power lenses and one negative power lens, and is a fourth lens L4, a fifth lens L5 and a sixth lens L6 respectively; the two positive focal power lens materials can be the same or different and are low dispersion materials; the fourth optical element G4 is a double-cemented lens assembly, and the focal power of the seventh lens element L7 on the object side is negative, and the focal power of the eighth lens element L8 on the image side is positive; in the fifth cemented lens group G5, the power of the ninth lens element L9 on the object side is negative, and the power of the tenth lens element L10 on the image side is positive; the sixth optical element G6 is a double-cemented lens assembly, and the focal power of the eleventh lens L11 on the object side is positive and the focal power of the twelfth lens L12 on the image side is negative; the seventh optical element G7 is a double-cemented lens assembly, and the power of the thirteenth lens element L13 on the object side is negative, and the power of the fourteenth lens element L14 on the image side is positive. The sixth optical element G6 and the seventh optical element G7 form two symmetrical double-cemented combinations, i.e., form a relatively symmetrical double-gaussian structure.

In this embodiment, the system focal length f is 4.5mm, the working distance is 0.15mm, the numerical aperture is 1.21, and the lens thickness and radius of the microscope objective lens are as shown in table 6 below:

surface of	Radius (mm)	Thickness (mm)	Nd	Vd
					S21	7.215	5	1.74	32.3
S20	5.516	1	1.76	52.3
					S19	3.256	4.3
S18	-3.154	1.5	1.88	40.8
					S17	-17.356	5.4	1.43	95
S16	-6.868	0.15
					S15	-35.214	4	1.43	95
S14	-7.689	2	1.61	44.3
					S13	-18.775	0.15
S12	26.365	4.5	1.43	95
					S11	-14.215	1.5	1.61	44.3
S10	-12.326	0.15
					S9	-26.117	4	1.43	95
S8	19.623	1.5	1.61	44.3
					S7	-18.366	4	1.43	95
S6	11.787	0.15
					S5	-19.733	2.8	1.43	95
S4	10.454	0.15
					S3	4.512	4.8	1.88	40.8
S2	4.357	1	1.52	32.2
					S1	Infinity	0.15

TABLE 6

Where radius refers to the radius of curvature of a surface and thickness refers to the on-axis distance from the current surface to the next surface, e.g., the thickness of surface S1 is the distance from S1 to S2, which may be the on-axis thickness of the medium or lens, or the on-axis air gap between them.

Fig. 22 is a transverse aberration diagram of the 0 field of view of the microscope objective lens according to the fifth embodiment, in which abscissa PY and PX represent normalized entrance pupil size, ordinate represents transverse aberration, scale is ± 5 μm, Y direction is a meridional direction, and X direction is a sagittal direction.

FIG. 23 is a transverse aberration diagram of the field of view 1 of the microscope objective lens according to the fifth embodiment, wherein the scale is + -5 μm, and the horizontal axis is close to the curve visible from the diagram, so that the microscope objective lens has better imaging performance.

Fig. 24 is a field curvature distortion diagram of a microscope objective lens of the fifth embodiment, the left diagram being a field curvature diagram in which the ordinate represents the field of view and the abscissa represents the field curvature in μm. The axial difference between the optimal focus point of the edge view field and the optimal focus point of the central view field is less than 2 lambda/NA²The theoretical value meets the requirement of clear full-field and flat-field objective lens. The ordinate in the figure is the normalized field of view; the abscissa represents the field curvature with a maximum value of 2 μm and a minimum value of-2 μm. The distortion graph is shown on the right, wherein the ordinate represents the field of view and the abscissa represents the distortion (percentage), and the distortion of the full field of view is less than 1%. In the figure, the ordinate is the normalized field of view and the abscissa represents the distortion, with a maximum of 1% and a minimum of-1%.

FIG. 25 is a chromatic aberration diagram of a microscope objective lens according to a fifth embodiment, in which the chromatic aberration of the full-wavelength curve is better corrected, and the difference between any two curves at each field is smaller than λ/NA²。

The large field-of-view, flat-field immersion microscope objective of this embodiment has a large object field of view (0.625 mm), which may be greater than 0.65mm in some preferred embodiments.

The above description is only one embodiment of the present invention, and is not intended to limit the present invention, and it is apparent to those skilled in the art that various modifications and variations can be made in the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.