KR20220128325A - Optical system - Google Patents

Abstract

An optical system according to an embodiment of the present invention comprises first to seventh lenses which are arranged in order from an object side toward an upper side. More specifically, the optical system comprises: the first lens which has positive refractive power, and has surfaces of the object side and the upper side formed to be convex and concave, respectively; the second lens which has negative refractive power, and has surfaces of the object side and the upper side formed to be convex and concave, respectively; the third lens which has positive refractive power; the fourth lens which has positive refractive power; the fifth lens which has negative refractive power; the sixth lens which has positive refractive power; and the seventh lens which has negative refractive power and has at least one inflection point on at least one surface of the object side and the upper side. When the greatest refractive index among the refractive indexes of the second lens, the third lens, and the fourth lens is defined as Nmax, the greatest refractive index satisfies 1.64 < Nmax <= 1.75. When the curvature radius of the object side surface of the sixth lenses is defined as Ri and the curvature radius of the upper side surface of the sixth lenses is defined as Rj, the curvature radiuses can satisfy -0.5 < (|Ri|-|Rj|)/(|Ri|+|Rj|) < 0.5. Therefore, the present invention can adjust the incident light quantity according to the brightness of the surrounding environment.

Description

imaging optical system

The present invention relates to an imaging optical system.

Recent portable terminals are equipped with cameras to enable video calls and photo taking. In addition, as the utilization of the camera mounted on the portable terminal increases, the demand for high resolution and high performance of the camera for the portable terminal is gradually increasing.

However, since portable terminals are gradually becoming smaller or lighter, there is a limit to realizing a high-resolution and high-performance camera.

In order to solve this problem, recently, a lens of a camera is made of a plastic material lighter than glass, and an imaging optical system is composed of 6 or more lenses to realize high resolution.

In addition, in order to realize a bright image even in a low-light environment, the imaging optical system is configured to have a small Fno value.

However, when the imaging optical system is configured to have a small Fno value, although a bright image can be realized, there is a problem in that it is difficult to implement a clear image because the depth is lowered.

An object of the present invention is to provide an imaging optical system capable of controlling an incident amount of light according to the illuminance of a surrounding environment and having a high resolution.

An imaging optical system according to an embodiment of the present invention includes: a first lens having a positive refractive power, a convex object-side surface and a concave image-side surface; a second lens having negative refractive power and having an object-side surface convex and an image-side surface concave; a third lens having positive refractive power; a fourth lens having positive refractive power; a fifth lens having a negative refractive power; a sixth lens having positive refractive power; and a seventh lens having a negative refractive power and having at least one inflection point on at least one of an object-side surface and an image-side surface, wherein the refractive index of the second lens, the refractive index of the third lens, and the refractive index of the fourth lens When the largest refractive index is Nmax, 1.64 < Nmax ≤ 1.75 is satisfied, the radius of curvature of the object-side surface of the sixth lens is Ri, and the radius of curvature of the image-side surface of the sixth lens is Rj, - 0.5 < (|Ri|-|Rj|)/(|Ri|+|Rj|) < 0.5 may be satisfied.

An imaging optical system according to an embodiment of the present invention has a high resolution, and can control an incident amount of light according to the illuminance of a surrounding environment.

1 is a view showing a state in which a variable diaphragm is maximally opened in an imaging optical system according to a first embodiment of the present invention;
2 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 1;
3 is a view showing a state in which the variable diaphragm is tightened in the imaging optical system according to the first embodiment of the present invention;
4 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 3;
5 is a view showing a state in which the variable diaphragm is maximally tightened in the imaging optical system according to the first embodiment of the present invention;
6 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 5;
7 is a view showing a state in which the variable diaphragm is maximally opened in the imaging optical system according to the second embodiment of the present invention;
8 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 7;
9 is a view showing a state in which the variable diaphragm is tightened in the imaging optical system according to the second embodiment of the present invention;
10 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 9;
11 is a view showing a state in which the variable diaphragm is maximally tightened in the imaging optical system according to the second embodiment of the present invention;
12 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 11;
13 is a view showing a state in which the variable diaphragm is maximally opened in the imaging optical system according to the third embodiment of the present invention;
14 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 13;
15 is a view showing a state in which the variable diaphragm is maximally tightened in the imaging optical system according to the third embodiment of the present invention;
16 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 15;
17 is a view showing a state in which the variable diaphragm is maximally opened in the imaging optical system according to the fourth embodiment of the present invention;
18 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 17;
19 is a view showing a state in which the variable diaphragm is tightened in the imaging optical system according to the fourth embodiment of the present invention;
20 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 19;
21 is a view showing a state in which the variable diaphragm is further tightened in the imaging optical system according to the fourth embodiment of the present invention;
22 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 21;
23 is a view showing a state in which the variable diaphragm is maximally tightened in the imaging optical system according to the fourth embodiment of the present invention;
24 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 23;
25 is a view showing a state in which the variable diaphragm is maximally opened in the imaging optical system according to the fifth embodiment of the present invention;
26 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 25;
27 is a view showing a state in which the variable diaphragm is maximally tightened in the imaging optical system according to the fifth embodiment of the present invention;
28 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 27;
29 is a view showing a state in which the variable diaphragm is maximally opened in the imaging optical system according to the sixth embodiment of the present invention;
30 is a curve showing the aberration characteristics of the imaging optical system shown in FIG. 29;
31 is a view showing a state in which the variable diaphragm is maximally tightened in the imaging optical system according to the sixth embodiment of the present invention;
FIG. 32 is a curve showing aberration characteristics of the imaging optical system shown in FIG. 31;

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiment.

For example, those skilled in the art who understand the spirit of the present invention will be able to easily suggest other embodiments included within the scope of the present invention through addition, change, or deletion of components, but this is also the spirit of the present invention will be considered to be within the scope of

In the following lens diagrams, the thickness, size, and shape of the lens are exaggerated for explanation, and in particular, the spherical or aspherical shape presented in the lens diagram is only presented as an example and is not limited thereto.

An imaging optical system according to an embodiment of the present invention may include a plurality of lenses disposed along an optical axis. The plurality of lenses may be disposed to be spaced apart from each other by a predetermined distance along the optical axis, respectively.

For example, the optical imaging system includes six or more lenses.

In the six-element embodiment, the first lens means the lens closest to the object side, and the sixth lens means the lens closest to the image sensor.

In the seven-element embodiment, the first lens means the lens closest to the object side, and the seventh lens means the lens closest to the image sensor.

In the eight-element embodiment, the first lens means the lens closest to the object side, and the eighth lens means the lens closest to the image sensor.

In addition, in each lens, the first surface means a surface close to the object side (or an object-side surface), and the second surface means a surface close to the image side (or an image side surface). In addition, in the present specification, all numerical values for the radius of curvature, thickness, distance, and effective aperture radius of the lens are in mm, and the unit of angle is Degree.

Meanwhile, the effective aperture radius refers to the radius of one surface (object-side surface and image-side surface) of each lens through which light actually passes. For example, the effective radius of the object-side surface of the first lens may mean a straight-line distance between an optical axis and an end at which light is incident on the object-side surface of the first lens.

In the description of the shape of each lens, the convex shape of one surface means that the paraxial region portion of the corresponding surface is convex, and the concave shape of one surface means that the paraxial region portion of the corresponding surface is concave. Therefore, even if it is described that one surface of the lens has a convex shape, the edge portion of the lens may be concave. Similarly, even if one surface of the lens is described as having a concave shape, the edge portion of the lens may be convex.

The paraxial region means a very narrow region near the optical axis.

An imaging optical system according to an embodiment of the present invention includes six or more lenses.

In the embodiment including six lenses, the imaging optical system includes a first lens, a second lens, a third lens, a fourth lens, a fifth lens and a sixth lens which are arranged in order from the object side.

In the embodiment including seven lenses, the imaging optical system includes a first lens, a second lens, a third lens, a fourth lens, a fifth lens, a sixth lens, and a seventh lens arranged in order from the object side do.

In the embodiment including eight lenses, the imaging optical system includes a first lens, a second lens, a third lens, a fourth lens, a fifth lens, a sixth lens, a seventh lens and a second lens arranged in order from the object side. Includes 8 lenses.

In addition, the optical imaging system according to the present invention may further include other components.

For example, the optical imaging system may further include an image sensor for converting an image of an incident subject into an electrical signal.

In addition, the imaging optical system may further include an infrared cut filter for blocking infrared rays. The infrared cut filter is disposed between the lens disposed closest to the image sensor and the image sensor.

In addition, the imaging optical system may further include a diaphragm for adjusting the amount of light. For example, a variable stop may be disposed in front of the first lens, and an aperture may be disposed between the second lens and the third lens.

The variable diaphragm is configured to be able to change its diameter.

All lenses constituting the imaging optical system according to an embodiment of the present invention may be made of a plastic material.

In addition, each of the plurality of lenses may have at least one aspherical surface.

That is, at least one of the first surface and the second surface of each lens may be an aspherical surface. Here, the aspherical surface of each lens is expressed by Equation (1).

In Equation 1, c is the curvature of the lens (the reciprocal of the radius of curvature), K is the conic constant, and Y is the distance from any point on the aspherical surface of the lens to the optical axis. In addition, constants A to H mean aspheric coefficients. And Z represents the distance from any point on the aspherical surface of the lens to the vertex of the aspherical surface.

The imaging optical system including the first to sixth lenses may have positive/positive/negative/positive/negative/negative refractive power in order from the object side.

The imaging optical system including the first to seventh lenses may have positive/negative/positive/positive/positive/positive/negative refractive power in order from the object side.

Alternatively, it may have a refractive power of positive/negative/positive/positive/positive/negative/negative.

Alternatively, it may have a refractive power of positive/negative/positive/positive/negative/positive/negative.

The imaging optical system including the first to eighth lenses may have positive/positive/positive/negative/negative/positive/positive/negative refractive power in order from the object side.

The optical imaging system according to an embodiment of the present invention may satisfy the following conditional expressions.

[Conditional Expression 1] TTL/IMGHT < 2.0

[Condition 2] FOV ≥ 70°

[Condition 3] 1.64 < Nmax ≤ 1.75

[Conditional Expression 4] 4.7 < TTL < 6.00

[Conditional Expression 5] 4.0 < f < 4.5

[Conditional Expression 6] f/EPD_max ≤ 1.7

[Conditional Expression 7] f/EPD_min > 2.0

[Conditional Expression 8] -0.5 < (|Ri|-|Rj|)/(|Ri|+|Rj|) < 0.5

[Conditional Expression 9] 0.8 < |Ri/Rj| ≤ 1.2

[Conditional Expression 10] f14 > f

In the conditional expressions, TTL is the distance on the optical axis from the object-side surface of the first lens to the imaging surface of the image sensor, IMGHT is half the diagonal length of the imaging surface of the image sensor, FOV is the angle of view of the imaging optical system, and Nmax is the second lens is the largest refractive index among the refractive index of , the refractive index of the third lens, and the refractive index of the fourth lens, f is the total focal length of the imaging optical system, EPD_max is the maximum diameter of the entrance pupil, EPD_min is the minimum diameter of the entrance pupil, and f14 is the first It is the combined focal length of the lens to the fourth lens.

Ri is the radius of curvature of the object-side surface of the lens disposed second closest to the image sensor, and Rj is the radius of curvature of the image-side surface of the lens disposed second closest to the image sensor. For example, in the six-element embodiment, Ri is the radius of curvature of the object-side surface of the fifth lens, and Rj is the radius of curvature of the image-side surface of the fifth lens. In the seven-element embodiment, Ri is the radius of curvature of the object-side surface of the sixth lens, and Rj is the radius of curvature of the image-side surface of the sixth lens. In the eight-element embodiment, Ri is the radius of curvature of the object-side surface of the seventh lens, and Rj is the radius of curvature of the image-side surface of the seventh lens.

In the imaging optical system configured as described above, since a plurality of lenses perform an aberration correction function, the aberration improvement performance may be improved.

An imaging optical system according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 6 .

1 and 2 show a state in which the variable diaphragm is maximally opened in the imaging optical system according to the first embodiment of the present invention, FIGS. 3 and 4 show a state in which the variable diaphragm is tightened, and FIGS. 5 and 6 indicates the state in which the variable iris is maximally tightened.

The imaging optical system according to the first embodiment of the present invention includes a first lens 110 , a second lens 120 , a third lens 130 , a fourth lens 140 , a fifth lens 150 , and a sixth lens. 160 and an optical system including a seventh lens 170 , and further includes an infrared cut filter 180 , an image sensor 190 and a variable stop (VST).

The lens characteristics of each lens (Radius of curvature, Thickness or Distance between lenses, Index, Abbe number, Effective aperture radius) Tables 1 to 3 are shown.

Table 1 shows the case where the diameter of the variable diaphragm is the largest.

Table 2 shows a case in which the diameter of the variable diaphragm becomes smaller than that of Table 1.

Table 3 shows the case where the diameter of the variable diaphragm is the minimum.

The imaging optical system according to the first embodiment of the present invention includes a variable stop (VST) disposed in front of the first lens 110 .

The variable stop VST is a device configured to selectively change the amount of light incident on the optical system including the first lens 110 to the seventh lens 170 . For example, in a low-illuminance environment, the diameter of the variable stop (VST) may be increased so that a relatively large amount of light is incident (see FIG. 1 and Table 1), and in a high-illuminance environment, a relatively small amount of light is variable The diameter of the diaphragm VST can be made small (refer to FIG. 5 and Table 3).

Meanwhile, the imaging optical system according to the first embodiment of the present invention may be configured such that Fno changes according to the diameter of the variable stop VST. Fno is a number representing the brightness of the optical system.

In the imaging optical system according to the first embodiment of the present invention, when the diameter of the variable stop (VST) is maximum, Fno may be smaller than 1.7, and when the diameter of the variable stop (VST) is minimum, Fno may be greater than 2.0 have.

In general, when the Fno value is changed, the focus position also changes. As an example, a focusing position when Fno is 1.5 and a focusing position when Fno is 2.4 may be different.

However, in the imaging optical system according to the first embodiment of the present invention, even when Fno is changed, the focus is focused on the same position, so that the image quality can be maintained constant.

2 is a curve showing aberration characteristics when the optical imaging system according to the first embodiment of the present invention has the smallest Fno value.

The curve on the left side of FIG. 2 shows the longitudinal spherical aberration of the imaging optical system for light of various wavelengths.

In the longitudinal spherical aberration curve of FIG. 2 , the horizontal axis represents the coefficient of the longitudinal spherical aberration, and the vertical axis represents the normalization of the distance from the optical axis to the effective aperture.

On the vertical axis of the longitudinal spherical aberration curve of FIG. 2 , when the distance from the optical axis to the effective aperture is 1, the point 0.25 may mean 25% of the distance from the optical axis to the effective aperture, and the point 0.75 is from the optical axis 75% of the distance to the effective opening.

The effective aperture is a stop that actually blocks light, and in the imaging optical system according to the first embodiment of the present invention, the variable stop VST disposed in front of the first lens serves as the effective aperture.

Referring to FIG. 2 , when the variable stop VST is maximally opened and Fno has the smallest value, the imaging optical system according to the first embodiment of the present invention has a longitudinal spherical surface with respect to light having a wavelength of 546.1 nm or more. The aberration may be configured to have a largest value at a position close to the optical axis and a smallest value at a position close to the effective aperture.

For example, the longitudinal spherical aberration may be configured to have a largest value at a point between 0 and 0.5 and a smallest value at a point between 0.5 and 1.0.

Alternatively, the longitudinal spherical aberration may be configured to have a largest value at a point between 0.2 and 0.3 and a smallest value at a point between 0.7 and 0.9.

For example, with respect to light having a wavelength of 546.1 nm or more, longitudinal spherical aberration may be the largest at 0.25 and the smallest at 0.75.

In addition, the imaging optical system according to the first embodiment of the present invention may be configured in a form in which the longitudinal spherical aberration curve has an inflection point.

In the first embodiment of the present invention, the first lens 110 has a positive refractive power, the first surface of the first lens 110 has a convex shape in the paraxial region, and the second surface of the first lens 110 has a It is concave in the paraxial region.

The second lens 120 has a negative refractive power, a first surface of the second lens 120 has a convex shape in the paraxial region, and a second surface of the second lens 120 has a concave shape in the paraxial region.

The first lens 110 and the second lens 120 may be made of a plastic material having different optical properties. For example, the difference between the Abbe's number between the first lens 110 and the second lens 120 may exceed 30.

The third lens 130 has a positive refractive power, a first surface of the third lens 130 has a convex shape in the paraxial region, and a second surface of the third lens 130 has a concave shape in the paraxial region.

The fourth lens 140 has a positive refractive power, a first surface of the fourth lens 140 has a convex shape in the paraxial region, and a second surface of the fourth lens 140 has a concave shape in the paraxial region.

The fifth lens 150 has a positive refractive power, and the first and second surfaces of the fifth lens 150 have a very large radius of curvature. The first surface of the fifth lens 150 has a concave shape in the paraxial region, and the second surface of the fifth lens 150 has a convex shape in the paraxial region.

The sixth lens 160 has a positive refractive power, and the first and second surfaces of the sixth lens 160 have a very large radius of curvature. The first and second surfaces of the sixth lens 160 are convex in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the sixth lens 160 . For example, the first surface of the sixth lens 160 may be convex in the paraxial region and concave toward the edge. The second surface of the sixth lens 160 may be convex in the paraxial region and concave toward the edge.

The seventh lens 170 has a negative refractive power, a first surface of the seventh lens 170 has a convex shape in the paraxial region, and a second surface of the seventh lens 170 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the seventh lens 170 . For example, the first surface of the seventh lens 170 may be convex in the paraxial region and concave toward the edge. The second surface of the seventh lens 170 may be concave in the paraxial region and convex toward the edge.

Meanwhile, each surface of the first lens 110 to the seventh lens 170 has an aspherical coefficient as shown in Table 4. For example, both the object-side surface and the image-side surface of the first lens 110 to the seventh lens 170 are aspherical.

An imaging optical system according to a second embodiment of the present invention will be described with reference to FIGS. 7 to 12 .

7 and 8 show a state in which the variable diaphragm is maximally opened in the imaging optical system according to the second embodiment of the present invention, FIGS. 9 and 10 show a state in which the variable diaphragm is tightened, and FIGS. 11 and 12 indicates the state in which the variable iris is maximally tightened.

The imaging optical system according to the second embodiment of the present invention includes a first lens 210 , a second lens 220 , a third lens 230 , a fourth lens 240 , a fifth lens 250 , and a sixth lens. 260 and an optical system including a seventh lens 270 , and further includes an infrared cut filter 280 , an image sensor 290 , a variable stop VST and an aperture ST.

The lens characteristics of each lens (Radius of curvature, Thickness or Distance between lenses, Index, Abbe number, Effective aperture radius) Tables 5 to 7 are shown.

Table 5 shows the case where the diameter of the variable diaphragm is the largest.

Table 6 shows a case in which the diameter of the variable diaphragm becomes smaller than that of Table 5.

Table 7 shows the case where the diameter of the variable diaphragm is the minimum.

The imaging optical system according to the second embodiment of the present invention includes a variable stop VST disposed in front of the first lens 210 and an aperture ST disposed between the second lens 220 and the third lens 230 . ) is included. However, the diaphragm ST may be disposed between the first lens 210 and the second lens 220 .

The variable diaphragm VST and the diaphragm ST are devices configured to selectively change the amount of light incident on the optical system including the first lens 210 to the seventh lens 270 . For example, in a low-illuminance environment, the diameter of the variable diaphragm (VST) may be increased so that a relatively large amount of light is incident (see FIGS. 7 and 5), and in a high-illuminance environment, a relatively small amount of light may be variable. The diameter of the diaphragm VST can be made small (refer FIG. 11 and Table 7).

Meanwhile, the imaging optical system according to the second exemplary embodiment of the present invention may be configured such that Fno changes according to the diameter of the variable stop VST. Fno is a number representing the brightness of the optical system.

In the imaging optical system according to the second embodiment of the present invention, Fno may be smaller than 1.7 when the diameter of the variable stop VST is maximum, and Fno may be greater than 2.0 when the diameter of the variable stop VST is the minimum. have.

In general, when the Fno value is changed, the focus position also changes. As an example, a focusing position when Fno is 1.6 and a focusing position when Fno is 2.1 may be different.

However, in the imaging optical system according to the second embodiment of the present invention, even when Fno is changed, the focus is focused on the same position, so that the image quality can be maintained constant.

8 is a curve showing aberration characteristics when the optical imaging system according to the second embodiment of the present invention has the smallest Fno value.

The curve on the left side of FIG. 8 shows the longitudinal spherical aberration of the imaging optical system for light of various wavelengths.

In the longitudinal spherical aberration curve of FIG. 8 , the horizontal axis represents the coefficient of the longitudinal spherical aberration, and the vertical axis represents the normalization of the distance from the optical axis to the effective aperture.

In the vertical axis of the longitudinal spherical aberration curve of FIG. 8 , when the distance from the optical axis to the effective aperture is 1, point 0.25 may mean 25% of the distance from the optical axis to the effective aperture, and point 0.75 is from the optical axis 75% of the distance to the effective opening.

The effective aperture is a stop that actually blocks light, and in the imaging optical system according to the second embodiment of the present invention, the variable stop VST or the stop ST serves as the effective aperture according to the diameter of the variable stop VST. . For example, when the variable diaphragm VST is maximally opened, the diaphragm ST serves as an effective opening, and when the variable diaphragm VST is maximally tightened, the variable diaphragm VST serves as an effective opening. .

Referring to FIG. 8 , when the variable stop VST is maximally opened and Fno has the smallest value, the imaging optical system according to the second embodiment of the present invention has a longitudinal spherical surface with respect to light having a wavelength of 555 nm or more. The aberration may be configured to have a largest value at a position close to the optical axis and a smallest value at a position close to the effective aperture.

For example, the longitudinal spherical aberration may be configured to have a largest value at a point between 0 and 0.5 and a smallest value at a point between 0.5 and 1.0.

Alternatively, the longitudinal spherical aberration may be configured to have a largest value at a point between 0.2 and 0.3 and a smallest value at a point between 0.7 and 0.9.

For example, with respect to light having a wavelength of 555 nm or more, longitudinal spherical aberration may be the largest at 0.25 and the smallest at 0.75.

In addition, the imaging optical system according to the second embodiment of the present invention may be configured in a form in which the longitudinal spherical aberration curve has an inflection point.

In the second embodiment of the present invention, the first lens 210 has a positive refractive power, the first surface of the first lens 210 has a convex shape in the paraxial region, and the second surface of the first lens 210 has a It is concave in the paraxial region.

The second lens 220 has a negative refractive power, a first surface of the second lens 220 has a convex shape in the paraxial region, and a second surface of the second lens 220 has a concave shape in the paraxial region.

The first lens 210 and the second lens 220 may be made of a plastic material having different optical properties. For example, a difference between the Abbe's number between the first lens 210 and the second lens 220 may exceed 30.

The third lens 230 has a positive refractive power, a first surface of the third lens 230 has a convex shape in the paraxial region, and a second surface of the third lens 230 has a concave shape in the paraxial region.

The fourth lens 240 has a positive refractive power, a first surface of the fourth lens 240 has a convex shape in the paraxial region, and a second surface of the fourth lens 240 has a concave shape in the paraxial region.

The fifth lens 250 has a positive refractive power, a first surface of the fifth lens 250 has a convex shape in the paraxial region, and a second surface of the fifth lens 250 has a concave shape in the paraxial region.

The sixth lens 260 has a negative refractive power, a first surface of the sixth lens 260 has a convex shape in the paraxial region, and a second surface of the sixth lens 260 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the sixth lens 260 . For example, the first surface of the sixth lens 260 may be convex in the paraxial region and concave toward the edge. The second surface of the sixth lens 260 may be concave in the paraxial region and convex toward the edge.

The seventh lens 270 has a negative refractive power, a first surface of the seventh lens 270 has a convex shape in the paraxial region, and a second surface of the seventh lens 270 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the seventh lens 270 . For example, the first surface of the seventh lens 270 may be convex in the paraxial region and concave toward the edge. The second surface of the seventh lens 270 may be concave in the paraxial region and convex toward the edge.

Meanwhile, each surface of the first lens 210 to the seventh lens 270 has an aspherical coefficient as shown in Table 8. As shown in FIG. For example, both the object-side surface and the image-side surface of the first lens 210 to the seventh lens 270 are aspherical.

An imaging optical system according to a third embodiment of the present invention will be described with reference to FIGS. 13 to 16 .

13 and 14 show a state in which the variable diaphragm is maximally opened in the imaging optical system according to the third embodiment of the present invention, and FIGS. 15 and 16 show a state in which the variable diaphragm is maximally tightened.

The imaging optical system according to the third embodiment of the present invention includes a first lens 310 , a second lens 320 , a third lens 330 , a fourth lens 340 , a fifth lens 350 , and a sixth lens. 360 and an optical system including a seventh lens 370 , and further includes an infrared cut filter 380 , an image sensor 390 , a variable diaphragm VST and a diaphragm ST.

The lens characteristics of each lens (Radius of curvature, Thickness or Distance between lenses, Index, Abbe number, Effective aperture radius) Table 9 and Table 10 are shown.

Table 9 shows the case where the diameter of the variable diaphragm is the largest.

Table 10 shows the case where the diameter of the variable diaphragm is the minimum.

The imaging optical system according to the third embodiment of the present invention includes a variable stop VST disposed in front of the first lens 310 and an aperture ST disposed between the second lens 320 and the third lens 330 . ) is included. However, the diaphragm ST may be disposed between the first lens 310 and the second lens 320 .

The variable diaphragm VST and the diaphragm ST are devices configured to selectively change the amount of light incident on the optical system including the first lens 310 to the seventh lens 370 . For example, in a low-illuminance environment, the diameter of the variable stop (VST) may be increased so that a relatively large amount of light is incident (see FIGS. 13 and 9), and in a high-illuminance environment, a relatively small amount of light may be variable. The diameter of the diaphragm VST can be made small (refer FIG. 15 and Table 10).

Meanwhile, the imaging optical system according to the third exemplary embodiment of the present invention may be configured such that Fno changes according to the diameter of the variable stop VST. Fno is a number representing the brightness of the optical system.

In the imaging optical system according to the third embodiment of the present invention, Fno may be smaller than 1.7 when the diameter of the variable stop VST is maximum, and Fno may be greater than 2.0 when the diameter of the variable stop VST is the minimum. have.

In general, when the Fno value is changed, the focus position also changes. As an example, a focusing position when Fno is 1.5 and a focusing position when Fno is 2.4 may be different.

However, in the imaging optical system according to the third embodiment of the present invention, even when Fno is changed, the focus is focused on the same position, so that the image quality can be maintained constant.

14 is a curve showing aberration characteristics when the optical imaging system according to the third embodiment of the present invention has the smallest Fno value.

The curve on the left side of FIG. 14 shows the longitudinal spherical aberration of the imaging optical system for light of various wavelengths.

In the longitudinal spherical aberration curve of FIG. 14 , the horizontal axis represents the coefficient of the longitudinal spherical aberration, and the vertical axis represents the normalization of the distance from the optical axis to the effective aperture.

In the longitudinal axis of the longitudinal spherical aberration curve of FIG. 14 , when the distance from the optical axis to the effective aperture is 1, the point 0.25 may mean 25% of the distance from the optical axis to the effective aperture, and the point 0.75 is from the optical axis. 75% of the distance to the effective opening.

The effective aperture is a stop that actually blocks light, and in the imaging optical system according to the third embodiment of the present invention, the variable stop VST or the stop ST serves as the effective aperture according to the diameter of the variable stop VST. . For example, when the variable diaphragm VST is maximally opened, the diaphragm ST serves as an effective opening, and when the variable diaphragm VST is maximally tightened, the variable diaphragm VST serves as an effective opening. .

Referring to FIG. 14 , when the variable stop VST is maximally opened and Fno has the smallest value, the imaging optical system according to the third embodiment of the present invention has a longitudinal spherical surface with respect to light having a wavelength of 546.1 nm or more. The aberration may be configured to have a largest value at a position close to the optical axis and a smallest value at a position close to the effective aperture.

For example, the longitudinal spherical aberration may be configured to have a largest value at a point between 0 and 0.5 and a smallest value at a point between 0.5 and 1.0.

Alternatively, the longitudinal spherical aberration may be configured to have a largest value at a point between 0.2 and 0.3 and a smallest value at a point between 0.7 and 1.0.

For example, with respect to light having a wavelength of 546.1 nm or more, longitudinal spherical aberration may be the largest at 0.25 and the smallest at 1.0.

In addition, the imaging optical system according to the third embodiment of the present invention may be configured in a form in which the longitudinal spherical aberration curve has an inflection point.

In the third embodiment of the present invention, the first lens 310 has positive refractive power, the first surface of the first lens 310 has a convex shape in the paraxial region, and the second surface of the first lens 310 has a It is concave in the paraxial region.

The second lens 320 has a negative refractive power, a first surface of the second lens 320 has a convex shape in the paraxial region, and a second surface of the second lens 320 has a concave shape in the paraxial region.

The first lens 310 and the second lens 320 may be made of a plastic material having different optical properties. For example, the difference between the Abbe's number between the first lens 310 and the second lens 320 may exceed 30.

The third lens 330 has positive refractive power, a first surface of the third lens 330 has a convex shape in the paraxial region, and a second surface of the third lens 330 has a concave shape in the paraxial region.

The fourth lens 340 has positive refractive power, and the first and second surfaces of the fourth lens 340 are convex in the paraxial region.

The fifth lens 350 has a positive refractive power, a first surface of the fifth lens 350 has a concave shape in the paraxial region, and a second surface of the fifth lens 350 has a convex shape in the paraxial region.

The sixth lens 360 has a negative refractive power, a first surface of the sixth lens 360 has a convex shape in the paraxial region, and a second surface of the sixth lens 360 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the sixth lens 360 . For example, the first surface of the sixth lens 360 may be convex in the paraxial region and concave toward the edge. The second surface of the sixth lens 360 may be concave in the paraxial region and convex toward the edge.

The seventh lens 370 has a negative refractive power, a first surface of the seventh lens 370 has a convex shape in the paraxial region, and a second surface of the seventh lens 370 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the seventh lens 370 . For example, the first surface of the seventh lens 370 may be convex in the paraxial region and concave toward the edge. The second surface of the seventh lens 370 may be concave in the paraxial region and convex toward the edge.

On the other hand, each surface of the first lens 310 to the seventh lens 370 has an aspherical coefficient as shown in Table 11 . For example, both the object-side surface and the image-side surface of the first lens 310 to the seventh lens 370 are aspherical.

An imaging optical system according to a fourth embodiment of the present invention will be described with reference to FIGS. 17 to 24 .

17 and 18 show a state in which the variable diaphragm is maximally opened in the imaging optical system according to the fourth embodiment of the present invention, FIGS. 19 and 20 show the state in which the variable diaphragm is tightened, and FIGS. 21 and 22 shows a state in which the variable diaphragm is further tightened, and FIGS. 23 and 24 show a state in which the variable diaphragm is maximally tightened.

The imaging optical system according to the fourth embodiment of the present invention includes a first lens 410 , a second lens 420 , a third lens 430 , a fourth lens 440 , a fifth lens 450 , and a sixth lens. 460 and an optical system including a seventh lens 470 , and further includes an infrared cut filter 480 , an image sensor 490 , a variable diaphragm (VST), and a diaphragm (ST).

The lens characteristics of each lens (Radius of curvature, Thickness or Distance between lenses, Index, Abbe number, Effective aperture radius) Tables 12 to 15 are shown.

Table 12 shows the case where the diameter of the variable diaphragm is the largest.

Table 13 shows the case where the diameter of the variable diaphragm is smaller than that of Table 12.

Table 14 shows a case in which the diameter of the variable diaphragm is smaller than that of Table 13.

Table 15 shows the case where the diameter of the variable diaphragm is the minimum.

An imaging optical system according to the fourth embodiment of the present invention includes a variable stop VST disposed in front of the first lens 410 and an aperture ST disposed between the second lens 420 and the third lens 430 . ) is included. However, the diaphragm ST may be disposed between the first lens 410 and the second lens 420 .

The variable diaphragm VST and the diaphragm ST are devices configured to selectively change the amount of light incident on the optical system including the first lens 410 to the seventh lens 470 . For example, in a low-illuminance environment, the diameter of the variable diaphragm (VST) may be increased so that a relatively large amount of light is incident (see FIGS. 17 and 12), and in a high-illuminance environment, a relatively small amount of light may be variable. The diameter of the diaphragm VST can be made small (refer FIG. 23 and Table 15).

Meanwhile, the imaging optical system according to the fourth embodiment of the present invention may be configured such that Fno changes according to the diameter of the variable stop VST. Fno is a number representing the brightness of the optical system.

In the imaging optical system according to the fourth embodiment of the present invention, Fno may be smaller than 1.7 when the diameter of the variable stop VST is maximum, and Fno may be greater than 2.0 when the diameter of the variable stop VST is the minimum. have.

In general, when the Fno value is changed, the focus position also changes. As an example, a focusing position when Fno is 1.5 and a focusing position when Fno is 2.6 may be different.

However, in the imaging optical system according to the fourth embodiment of the present invention, even when Fno is changed, the focus is focused on the same position, so that the image quality can be maintained constant.

18 is a curve showing aberration characteristics when the optical imaging system according to the fourth embodiment of the present invention has the smallest Fno value.

The curve on the left side of FIG. 18 shows the longitudinal spherical aberration of the imaging optical system for light of various wavelengths.

In the longitudinal spherical aberration curve of FIG. 18 , the horizontal axis represents the coefficient of the longitudinal spherical aberration, and the vertical axis represents the normalization of the distance from the optical axis to the effective aperture.

In the vertical axis of the longitudinal spherical aberration curve of FIG. 18 , when the distance from the optical axis to the effective aperture is 1, the point 0.25 may mean 25% of the distance from the optical axis to the effective aperture, and the point 0.75 is from the optical axis. 75% of the distance to the effective opening.

The effective aperture is a stop that actually blocks light, and in the imaging optical system according to the fourth embodiment of the present invention, the variable stop VST or the stop ST serves as the effective aperture depending on the diameter of the variable stop VST. . For example, when the variable diaphragm VST is maximally opened, the diaphragm ST serves as an effective opening, and when the variable diaphragm VST is maximally tightened, the variable diaphragm VST serves as an effective opening. .

Referring to FIG. 18 , when the variable stop VST is maximally opened and Fno has the smallest value, the imaging optical system according to the fourth embodiment of the present invention has a longitudinal spherical surface with respect to light having a wavelength of 555 nm or more. The aberration may be configured to have a largest value at a position close to the optical axis and a smallest value at a position close to the effective aperture.

For example, the longitudinal spherical aberration may be configured to have a largest value at a point between 0 and 0.5 and a smallest value at a point between 0.5 and 1.0.

Alternatively, the longitudinal spherical aberration may be configured to have a largest value at a point between 0.2 and 0.3 and a smallest value at a point between 0.7 and 0.9.

For example, with respect to light having a wavelength of 555 nm or more, longitudinal spherical aberration may be the largest at 0.25 and the smallest at 0.75.

In addition, the imaging optical system according to the fourth embodiment of the present invention may be configured in a form in which the longitudinal spherical aberration curve has an inflection point.

In the fourth embodiment of the present invention, the first lens 410 has a positive refractive power, the first surface of the first lens 410 is convex in the paraxial region, and the second surface of the first lens 410 is It is concave in the paraxial region.

The second lens 420 has a negative refractive power, a first surface of the second lens 420 has a convex shape in the paraxial region, and a second surface of the second lens 420 has a concave shape in the paraxial region.

The first lens 410 and the second lens 420 may be made of a plastic material having different optical properties. For example, the difference between the Abbe's number between the first lens 410 and the second lens 420 may exceed 30.

The third lens 430 has positive refractive power, a first surface of the third lens 430 has a convex shape in the paraxial region, and a second surface of the third lens 430 has a concave shape in the paraxial region.

The fourth lens 440 has positive refractive power, and the first and second surfaces of the fourth lens 440 are convex in the paraxial region.

The fifth lens 450 has a negative refractive power, a first surface of the fifth lens 450 has a concave shape in the paraxial region, and a second surface of the fifth lens 450 has a convex shape in the paraxial region.

The sixth lens 460 has positive refractive power, a first surface of the sixth lens 460 has a convex shape in the paraxial region, and a second surface of the sixth lens 460 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the sixth lens 460 . For example, the first surface of the sixth lens 460 may be convex in the paraxial region and concave toward the edge. The second surface of the sixth lens 460 may be concave in the paraxial region and convex toward the edge.

The seventh lens 470 has a negative refractive power, a first surface of the seventh lens 470 has a convex shape in the paraxial region, and a second surface of the seventh lens 470 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the seventh lens 470 . For example, the first surface of the seventh lens 470 may be convex in the paraxial region and concave toward the edge. The second surface of the seventh lens 470 may be concave in the paraxial region and convex toward the edge.

Meanwhile, each surface of the first lens 410 to the seventh lens 470 has an aspherical coefficient as shown in Table 16. As shown in FIG. For example, both the object-side surface and the image-side surface of the first lens 410 to the seventh lens 470 are aspherical.

An imaging optical system according to a fifth embodiment of the present invention will be described with reference to FIGS. 25 to 28 .

25 and 26 show a state in which the variable diaphragm is maximally opened in the imaging optical system according to the fifth embodiment of the present invention, and FIGS. 27 and 28 show a state in which the variable diaphragm is maximally tightened.

The imaging optical system according to the fifth embodiment of the present invention includes a first lens 510 , a second lens 520 , a third lens 530 , a fourth lens 540 , a fifth lens 550 , and a sixth lens. It includes an optical system having a 560 , and further includes an infrared cut filter 570 , an image sensor 580 , a variable diaphragm (VST), and a diaphragm (ST).

The lens characteristics of each lens (Radius of curvature, Thickness or Distance between lenses, Index, Abbe number, Effective aperture radius) Table 17 and Table 18 are shown.

Table 17 shows the case where the diameter of the variable diaphragm is the largest.

Table 18 shows the case where the diameter of the variable diaphragm is the minimum.

An imaging optical system according to the fifth embodiment of the present invention includes a variable stop VST disposed in front of the first lens 510 and an aperture ST disposed between the second lens 520 and the third lens 530 . ) is included. However, the diaphragm ST may be disposed between the first lens 510 and the second lens 520 .

The variable diaphragm VST and the diaphragm ST are devices configured to selectively change the amount of light incident on the optical system including the first lens 510 to the sixth lens 560 . For example, in a low-illuminance environment, the diameter of the variable diaphragm (VST) may be increased so that a relatively large amount of light is incident (see FIGS. 25 and 17), and in a high-illuminance environment, a relatively small amount of light is variable. The diameter of the diaphragm VST can be made small (refer FIG. 27 and Table 18).

Meanwhile, the imaging optical system according to the fifth embodiment of the present invention may be configured such that Fno changes according to the diameter of the variable stop VST. Fno is a number representing the brightness of the optical system.

In the imaging optical system according to the fifth embodiment of the present invention, Fno may be smaller than 1.7 when the diameter of the variable stop VST is maximum, and Fno may be greater than 2.0 when the diameter of the variable stop VST is the minimum. have.

In general, when the Fno value is changed, the focus position also changes. As an example, a focusing position when Fno is 1.7 and a focusing position when Fno is 2.6 may be different.

However, the imaging optical system according to the fifth embodiment of the present invention can keep the image quality constant by focusing on the same position even when Fno is changed.

26 is a curve showing aberration characteristics when the optical imaging system according to the fifth embodiment of the present invention has the smallest Fno value.

The curve on the left side of FIG. 26 shows the longitudinal spherical aberration of the imaging optical system for light of various wavelengths.

In the longitudinal spherical aberration curve of FIG. 26, the horizontal axis represents the coefficient of the longitudinal spherical aberration, and the vertical axis represents the normalization of the distance from the optical axis to the effective aperture.

In the longitudinal axis of the longitudinal spherical aberration curve of FIG. 26 , when the distance from the optical axis to the effective aperture is 1, point 0.25 may mean 25% of the distance from the optical axis to the effective aperture, and point 0.75 is from the optical axis 75% of the distance to the effective opening.

The effective aperture is a stop that actually blocks light, and in the imaging optical system according to the fifth embodiment of the present invention, the variable stop VST or the stop ST serves as the effective aperture according to the diameter of the variable stop VST. . For example, when the variable diaphragm VST is maximally opened, the diaphragm ST serves as an effective opening, and when the variable diaphragm VST is maximally tightened, the variable diaphragm VST serves as an effective opening. .

Referring to FIG. 26 , when the variable stop VST is maximally opened and Fno has the smallest value, the imaging optical system according to the fifth embodiment of the present invention has a longitudinal spherical surface with respect to light having a wavelength of 555 nm or more. The aberration may be configured to have a largest value at a position close to the optical axis and a smallest value at a position close to the effective aperture.

For example, the longitudinal spherical aberration may be configured to have a largest value at a point between 0 and 0.5 and a smallest value at a point between 0.5 and 1.0.

For example, with respect to light having a wavelength of 555 nm or more, the longitudinal spherical aberration may be the largest at the point 0.4 and the smallest at the point 0.75.

In addition, the optical imaging system according to the fifth embodiment of the present invention may be configured in a form in which the longitudinal spherical aberration curve has an inflection point.

In the fifth embodiment of the present invention, the first lens 510 has positive refractive power, the first surface of the first lens 510 is convex in the paraxial region, and the second surface of the first lens 510 has a It is concave in the paraxial region.

The second lens 520 has a positive refractive power, and the first and second surfaces of the second lens 520 are convex in the paraxial region.

The third lens 530 has a negative refractive power, a first surface of the third lens 530 has a convex shape in the paraxial region, and a second surface of the third lens 530 has a concave shape in the paraxial region.

The fourth lens 540 has positive refractive power, and the first and second surfaces of the fourth lens 540 are convex in the paraxial region.

The fifth lens 550 has a negative refractive power, a first surface of the fifth lens 550 has a convex shape in the paraxial region, and a second surface of the fifth lens 550 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the fifth lens 550 . For example, the first surface of the fifth lens 550 may be convex in the paraxial region and concave toward the edge. The second surface of the fifth lens 550 may be concave in the paraxial region and convex toward the edge.

The sixth lens 560 has a negative refractive power, a first surface of the sixth lens 560 has a convex shape in the paraxial region, and a second surface of the sixth lens 560 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the sixth lens 560 . For example, the first surface of the sixth lens 560 may be convex in the paraxial region and concave toward the edge. The second surface of the sixth lens 560 may be concave in the paraxial region and convex toward the edge.

Meanwhile, each surface of the first lens 510 to the sixth lens 560 has an aspherical coefficient as shown in Table 19. As shown in FIG. For example, both the object-side surface and the image-side surface of the first lens 510 to the sixth lens 560 are aspherical.

An imaging optical system according to a sixth embodiment of the present invention will be described with reference to FIGS. 29 to 32 .

29 and 30 show a state in which the variable diaphragm is maximally opened in the imaging optical system according to the sixth embodiment of the present invention, and FIGS. 31 and 32 show a state in which the variable diaphragm is maximally tightened.

The imaging optical system according to the sixth embodiment of the present invention includes a first lens 610 , a second lens 620 , a third lens 630 , a fourth lens 640 , a fifth lens 650 , and a sixth lens. 660 , an optical system including a seventh lens 670 and an eighth lens 680 , and an infrared cut filter 690 , an image sensor 700 , a variable diaphragm (VST), and an iris (ST) include

The lens characteristics of each lens (Radius of curvature, Thickness or Distance between lenses, Index, Abbe number, Effective aperture radius) Table 20 and Table 21 are shown.

Table 20 shows the case where the diameter of the variable diaphragm is the largest.

Table 21 shows the case where the diameter of the variable diaphragm is the minimum.

The imaging optical system according to the sixth embodiment of the present invention includes a variable stop VST disposed in front of the first lens 610 and an aperture ST disposed between the second lens 620 and the third lens 630 . ) is included. However, the diaphragm ST may be disposed between the first lens 610 and the second lens 620 .

The variable diaphragm VST and the diaphragm ST are devices configured to selectively change the amount of light incident on the optical system including the first lens 610 to the eighth lens 680 . For example, in a low-illuminance environment, the diameter of the variable stop (VST) may be increased so that a relatively large amount of light is incident (see FIG. 29 and Table 20), and in a high-illuminance environment, a relatively small amount of light may be variable. The diameter of the diaphragm VST can be made small (refer FIG. 31 and Table 21).

Meanwhile, the optical imaging system according to the sixth embodiment of the present invention may be configured such that Fno changes according to the diameter of the variable stop VST. Fno is a number representing the brightness of the optical system.

In the imaging optical system according to the sixth embodiment of the present invention, Fno may be smaller than 1.7 when the diameter of the variable stop VST is maximum, and Fno may be greater than 2.0 when the diameter of the variable stop VST is the minimum. have.

In general, when the Fno value is changed, the focus position also changes. As an example, a focusing position when Fno is 1.6 and a focusing position when Fno is 2.6 may be different.

However, the imaging optical system according to the sixth embodiment of the present invention can keep the image quality constant by focusing on the same position even when Fno is changed.

30 is a curve showing aberration characteristics when the optical imaging system according to the sixth embodiment of the present invention has the smallest Fno value.

The curve on the left side of FIG. 30 shows the longitudinal spherical aberration of the imaging optical system for light of various wavelengths.

In the longitudinal spherical aberration curve of FIG. 30 , the horizontal axis represents the coefficient of the longitudinal spherical aberration, and the vertical axis represents the normalization of the distance from the optical axis to the effective aperture.

In the longitudinal axis of the longitudinal spherical aberration curve of FIG. 30 , when the distance from the optical axis to the effective aperture is 1, point 0.25 may mean 25% of the distance from the optical axis to the effective aperture, and point 0.75 is from the optical axis 75% of the distance to the effective opening.

The effective aperture is a stop that actually blocks light, and in the imaging optical system according to the sixth embodiment of the present invention, the variable stop VST or the stop ST serves as the effective aperture depending on the diameter of the variable stop VST. . For example, when the variable diaphragm VST is maximally opened, the diaphragm ST serves as an effective opening, and when the variable diaphragm VST is maximally tightened, the variable diaphragm VST serves as an effective opening. .

Referring to FIG. 30 , when the variable stop VST is maximally opened and Fno has the smallest value, the imaging optical system according to the sixth embodiment of the present invention has a longitudinal spherical surface with respect to light having a wavelength of 546.1 nm or more. The aberration may be configured to have a largest value at a position close to the optical axis and a smallest value at a position close to the effective aperture.

For example, the longitudinal spherical aberration may be configured to have a largest value at a point between 0 and 0.5 and a smallest value at a point between 0.5 and 1.0.

For example, with respect to light having a wavelength of 546.1 nm or more, longitudinal spherical aberration may be the largest at 0.4 and the smallest at 1.0.

Also, the optical imaging system according to the sixth embodiment of the present invention may be configured in such a way that the longitudinal spherical aberration curve has an inflection point.

In the sixth embodiment of the present invention, the first lens 610 has a positive refractive power, the first surface of the first lens 610 is convex in the paraxial region, and the second surface of the first lens 610 is It is concave in the paraxial region.

The second lens 620 has a positive refractive power, a first surface of the second lens 620 has a convex shape in the paraxial region, and a second surface of the second lens 620 has a concave shape in the paraxial region.

The third lens 630 has positive refractive power, and the first and second surfaces of the third lens 630 are convex in the paraxial region.

The fourth lens 640 has a negative refractive power, a first surface of the fourth lens 640 has a convex shape in the paraxial region, and a second surface of the fourth lens 640 has a concave shape in the paraxial region.

The fifth lens 650 has a negative refractive power, a first surface of the fifth lens 650 has a convex shape in the paraxial region, and a second surface of the fifth lens 650 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the fifth lens 650 . For example, the first surface of the fifth lens 650 may be convex in the paraxial region and concave toward the edge. The second surface of the fifth lens 650 may be concave in the paraxial region and convex toward the edge.

The sixth lens 660 has a positive refractive power, a first surface of the sixth lens 660 has a concave shape in the paraxial region, and a second surface of the sixth lens 660 has a convex shape in the paraxial region.

The seventh lens 670 has positive refractive power, and a first surface of the seventh lens 670 has a convex shape in the paraxial region, and a second surface of the seventh lens 670 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the seventh lens 670 . For example, the first surface of the seventh lens 670 may be convex in the paraxial region and concave toward the edge. The second surface of the seventh lens 670 may be concave in the paraxial region and convex toward the edge.

The eighth lens 680 has a negative refractive power, a first surface of the eighth lens 680 has a convex shape in the paraxial region, and a second surface of the eighth lens 680 has a concave shape in the paraxial region.

In addition, at least one inflection point is formed on at least one of the first and second surfaces of the eighth lens 680 . For example, the first surface of the eighth lens 680 may be convex in the paraxial region and concave toward the edge. The second surface of the eighth lens 680 may be concave in the paraxial region and convex toward the edge.

Meanwhile, each surface of the first lens 610 to the eighth lens 680 has an aspherical coefficient as shown in Table 22. As shown in FIG. For example, both the object-side surface and the image-side surface of the first lens 610 to the eighth lens 680 are aspherical.

In the above, the configuration and features of the present invention have been described based on the embodiments according to the present invention, but the present invention is not limited thereto, and it is understood that various changes or modifications can be made within the spirit and scope of the present invention. It is intended that such changes or modifications will be apparent to those skilled in the art, and therefore fall within the scope of the appended claims.

110, 210, 310, 410, 510, 610: first lens
120, 220, 320, 420, 520, 620: second lens
130, 230, 330, 430, 530, 630: third lens
140, 240, 340, 440, 540, 640: fourth lens
150, 250, 350, 450, 550, 650: fifth lens
160, 260, 360, 460, 560, 660: sixth lens
170, 270, 370, 470, 670: 7th lens
680: eighth lens
180, 280, 380, 480, 570, 690: infrared cut filter
190, 290, 390, 490, 580, 700: image sensor
VST: Variable Aperture
ST: aperture

Claims (13)

arranged in order from the object side toward the upper side,
a first lens having positive refractive power and having a convex object-side surface and a concave image-side surface;
a second lens having negative refractive power and having an object-side surface convex and an image-side surface concave;
a third lens having positive refractive power;
a fourth lens having positive refractive power;
a fifth lens having a negative refractive power;
a sixth lens having positive refractive power; and
A seventh lens having a negative refractive power and having at least one inflection point on at least one of an object-side surface and an image-side surface;
When the largest refractive index among the refractive index of the second lens, the refractive index of the third lens, and the refractive index of the fourth lens is Nmax,
1.64 < Nmax ≤ 1.75,
When the radius of curvature of the object-side surface of the sixth lens is Ri, and the radius of curvature of the image-side surface of the sixth lens is Rj,
An imaging optical system satisfying -0.5 < (|Ri|-|Rj|)/(|Ri|+|Rj|) < 0.5.
According to claim 1,
When the distance from the object-side surface of the first lens to the imaging plane is TTL, and a half of the diagonal length of the imaging plane is IMGHT,
An imaging optical system satisfying TTL/IMGHT < 2.0.
According to claim 1,
When the field of view of the optical system including the first lens to the seventh lens is FOV,
An imaging optical system that satisfies FOV ≥ 70°.
According to claim 1,
When the combined focal length of the first lens to the fourth lens is f14, and f is the total focal length of the optical system including the first lens to the seventh lens,
An imaging optical system satisfying f14 > f.
According to claim 1,
The third lens is an imaging optical system in which the object-side surface is convex and the image-side surface is concave.
6. The method of claim 5,
The fourth lens is an imaging optical system in which an object-side surface is convex.
7. The method of claim 6,
The sixth lens is an imaging optical system in which an object-side surface is convex.
8. The method of claim 7,
The seventh lens is an imaging optical system in which the image side surface is concave in the paraxial region.
arranged in order from the object side toward the upper side,
a first lens having positive refractive power and having a convex object-side surface and a concave image-side surface;
a second lens having positive refractive power and having a convex object-side surface;
a third lens having negative refractive power and having an object-side surface convex and an image-side surface concave;
a fourth lens having positive refractive power;
a fifth lens having negative refractive power and having at least one inflection point on at least one of an object-side surface and an image-side surface; and
A sixth lens having a negative refractive power and having at least one inflection point on at least one of an object-side surface and an image-side surface;
When the distance from the object-side surface of the first lens to the imaging plane is TTL, and a half of the diagonal length of the imaging plane is IMGHT,
TTL/IMGHT <2.0;
When the radius of curvature of the object-side surface of the fifth lens is Ri, and the radius of curvature of the image-side surface of the fifth lens is Rj,
An imaging optical system satisfying -0.5 < (|Ri|-|Rj|)/(|Ri|+|Rj|) < 0.5.
10. The method of claim 9,
When the largest refractive index among the refractive index of the second lens, the refractive index of the third lens, and the refractive index of the fourth lens is Nmax,
1.64 < Nmax ≤ 1.75,
10. The method of claim 9,
When the field of view of the optical system including the first lens to the seventh lens is FOV,
An imaging optical system that satisfies FOV ≥ 70°.
10. The method of claim 9,
The fourth lens is an imaging optical system in which an image side surface is convex.
13. The method of claim 12,
The sixth lens has a convex object-side surface and a concave image-side surface of the sixth lens.

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