OPTICAL LENS, CAMERA MODULE, AND ELECTRONIC DEVICE

Abstract

This application provides an optical lens, a camera module, and an electronic device. The optical lens includes a first lens, a second lens, a third lens, a fourth lens, a fifth lens, and a sixth lens that are sequentially arranged from an object side to an image side. The first lens, the third lens, and the fifth lens all have positive focal power, the second lens and the fourth lens both have negative focal power, and the sixth lens has positive focal power or negative focal power. Object side surfaces and image side surfaces of the first lens to the sixth lens include at least one anamorphic aspherical surface. When the optical lens is applied to the camera module and the electronic device, the camera module and the electronic device can implement ultra-wide-angle photographing, and can also resolve a distortion problem in ultra-wide-angle imaging to a large degree.

Claims

1. An optical lens, comprising a first lens, a second lens, a third lens, a fourth lens, a fifth lens, and a sixth lens that are sequentially arranged from an object side to an image side, wherein the first lens, the third lens, and the fifth lens all have positive focal power, the second lens and the fourth lens both have negative focal power, and the sixth lens has positive focal power or negative focal power; and object side surfaces and image side surfaces of lenses from the first lens to the sixth lens comprise at least one anamorphic aspherical surface.

2. The optical lens according to claim 1, wherein a focal length f1 of the first lens and a focal length f2 of the second lens meet −0.5<f2/f1<−0.01.

3. The optical lens according to claim 2, wherein a focal length f3 of the third lens and a focal length f4 of the fourth lens meet −4<f4/f3<0.

4. The optical lens according to claim 3, wherein a focal length f5 of the fifth lens and a focal length f of the optical lens meet 0.1<f5/f<1.5.

5. The optical lens according to claim 1, wherein a curvature radius R6 of the image side surface of the third lens and a curvature radius R10 of the image side surface of the fifth lens meet 0<R6/R10<2.9.

6. The optical lens according to claim 1, wherein a distance T45 between the fourth lens and the fifth lens and the focal length f of the optical lens meet 0.05<T45/f<0.4.

7. The optical lens according to claim 6, wherein the optical lens meets the following: 0<(T23+T56)/TTL<0.5, wherein T23 is a distance between the second lens and the third lens, T56 is a distance between the fifth lens and the sixth lens, and TTL is a distance from the object side surface of the first lens to an imaging plane in an optical axis direction of the optical lens.

8. The optical lens according to claim 1, wherein the at least one anamorphic aspherical surface comprises a first vertex and a second vertex, the first vertex and the second vertex are located in an optical effective region of the anamorphic aspherical surface, and are both located on a sagittal plane of a lens in which the anamorphic aspherical surface is located, and the first vertex and the second vertex are symmetric with respect to a meridional plane of the lens in which the anamorphic aspherical surface is located; and a distance from the first vertex to a first reference plane is equal to a distance from the second vertex to the first reference plane, the first reference plane is perpendicular to an optical axis of the optical lens, and a point at which the optical axis of the optical lens intersects the anamorphic aspherical surface is located on the first reference plane.

9. The optical lens according to claim 8, wherein the anamorphic aspherical surface further comprises a third vertex and a fourth vertex, the third vertex and the fourth vertex are both located in the optical effective region of the anamorphic aspherical surface, and are both located on the meridional plane of the lens in which the anamorphic aspherical surface is located, and the third vertex and the fourth vertex are symmetric with respect to the sagittal plane of the lens in which the anamorphic aspherical surface is located; and a distance from the third vertex to the first reference plane is equal to a distance from the fourth vertex to the first reference plane.

10. The optical lens according to claim 1, wherein the optical lens comprises a stop, and the stop is located between the second lens and the third lens.

11. The optical lens according to claim 1, wherein the optical lens meets |TDT|≤5.0%, and TDT is a maximum value of TV distortion in an imaging range of the optical lens.

12. The optical lens according to claim 1, wherein the optical lens meets 100°≤FOV≤140°, and FOV is a field of view of the camera lens group.

13. The optical lens according to claim 1, wherein the optical lens meets the following: 0<ImagH/TTL<1, wherein TTL is the distance from the object side surface of the first lens to the imaging plane in the optical axis direction of the optical lens, and ImagH is an imaging height on the imaging plane.

14. A camera module, comprising a circuit board, a photosensitive chip, and the optical lens according to claim 1, wherein the photosensitive chip and the optical lens are both fastened to the circuit board, and the optical lens is configured to project ambient light to the photosensitive chip.

15. An electronic device, comprising a housing, a camera module that is mounted in the housing and comprises a circuit board, a photosensitive chip, and a optical lens, wherein the photosensitive chip and the optical lens are both fastened to the circuit board, wherein the optical lens is configured to project ambient light to the photosensitive chip and comprises a first lens, a second lens, a third lens, a fourth lens, a fifth lens, and a sixth lens that are sequentially arranged from an object side to an image side, wherein the first lens, the third lens, and the fifth lens all have positive focal power, the second lens and the fourth lens both have negative focal power, and the sixth lens has positive focal power or negative focal power; and object side surfaces and image side surfaces of lenses from the first lens to the sixth lens comprise at least one anamorphic aspherical surface.

16. The optical lens according to claim 15, wherein a focal length f1 of the first lens and a focal length f2 of the second lens meet −0.5<f2/f1<−0.01.

17. The optical lens according to claim 16, wherein a focal length f3 of the third lens and a focal length f4 of the fourth lens meet −4<f4/f3<0.

18. The optical lens according to claim 17, wherein a focal length f5 of the fifth lens and a focal length f of the optical lens meet 0.1<f5/f<1.5.

19. The optical lens according to claim 15, wherein a curvature radius R6 of the image side surface of the third lens and a curvature radius R10 of the image side surface of the fifth lens meet 0<R6/R10<2.9.

20. The optical lens according to claim 15, wherein a distance T45 between the fourth lens and the fifth lens and the focal length f of the optical lens meet 0.05<T45/f<0.4.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0049] FIG. 1 is a schematic diagram of a structure of an electronic device according to an embodiment of this application;

[0050] FIG. 2 is a partial schematic exploded view of the electronic device shown in FIG. 1;

[0051] FIG. 3 is a partial schematic cross-sectional diagram of the electronic device shown in FIG. 1 at a line A-A;

[0052] FIG. 4 is a schematic exploded view of a camera module of the electronic device shown in FIG. 1;

[0053] FIG. 5 is a schematic structural diagram of an optical lens of the camera module shown in FIG. 4;

[0054] FIG. 6 is a schematic planar diagram of an object side surface of a sixth lens of the optical lens shown in FIG. 5;

[0055] FIG. 7 is a schematic cross-sectional diagram of the sixth lens shown in FIG. 6 on a sagittal plane;

[0056] FIG. 8 is a schematic cross-sectional diagram of the sixth lens shown in FIG. 6 on a meridional plane;

[0057] FIG. 9 is a schematic planar diagram of an image side surface of a sixth lens of the optical lens shown in FIG. 6;

[0058] FIG. 10 is a schematic structural diagram of an implementation of lenses of the optical lens shown in FIG. 5;

[0059] FIG. 11 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 10;

[0060] FIG. 12 is a schematic structural diagram of another implementation of lenses of the optical lens shown in FIG. 5;

[0061] FIG. 13 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 12;

[0062] FIG. 14 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5;

[0063] FIG. 15 is an imaging simulation diagram of each lens of the optical lens shown in FIG.

[0064] FIG. 16 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5;

[0065] FIG. 17 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 16;

[0066] FIG. 18 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5;

[0067] FIG. 19 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 18;

[0068] FIG. 20 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5;

[0069] FIG. 21 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 20;

[0070] FIG. 22 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5;

[0071] FIG. 23 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 22;

[0072] FIG. 24 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5;

[0073] FIG. 25 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 24;

[0074] FIG. 26 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5;

[0075] FIG. 27 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 26;

[0076] FIG. 28 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5; and

[0077] FIG. 29 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 28.

DESCRIPTION OF EMBODIMENTS

[0078] To facilitate understanding of an optical lens provided in the embodiments of this application, related nouns used in this application are explained.

[0079] An optical axis is an axis passing through a center of each lens.

[0080] When a lens is used as a boundary, a side on which a photographed object is located is an object side, and a surface of the lens that is close to the object side is referred to as an object side surface.

[0081] When a lens is used as a boundary, a side on which an image of a photographed object is located is an image side, and a surface of the lens that is close to the image side is referred to as an image side surface.

[0082] Positive focal power may also be referred to as positive refractive power, and indicates that a lens has a positive focal length.

[0083] Negative focal power may also be referred to as negative refractive power, and indicates that a lens has a negative focal length.

[0084] A focal length (focal length), also referred to as a focal length, is a measurement manner of measuring convergence or divergence of light in an optical system, and is a vertical distance from an optical center of a lens or a lens group to a focal plane when a clear image of an infinite scene is formed on the focal plane by using the lens or the lens group. From a practical perspective, the focal length may be understood as a distance from a center of a lens to an imaging plane. A position of an optical center of a fixed-focus lens is fixed.

[0085] Field of view (field of view, FOV): In an optical instrument, a lens of the optical instrument is used as a vertex, and an included angle formed by two edges of a maximum range that an object image of a measured object can pass through the lens is referred to as a field of view. The field of view determines a view range of the optical instrument. A larger field of view indicates a larger view range and a smaller optical rate.

[0086] An aperture is an apparatus configured to control an amount of light passing through a lens, and is usually in the lens. A size of the aperture may be represented by an F-number (symbol: Fno).

[0087] The F-number is a ratio (a reciprocal of a relative aperture) of a focal length of a lens to a diameter of a clear aperture of the lens. A smaller F-number indicates a larger amount of admitted light in a same unit of time. A larger F-number indicates a smaller depth of field, so that photographed background content is blurred. This is similar to an effect achieved by a long-focus lens.

[0088] A total track length (total track length, TTL) is a distance from an object side surface of a first lens of an optical lens to an imaging plane in a direction from an object side to an image side.

[0089] An entrance pupil diameter (entrance pupil diameter, EPD) is a ratio of a focal length of the optical lens to the F-number.

[0090] The Abbe number, namely, a dispersion coefficient, is a ratio between differences between refractive indexes of an optical material at different wavelengths, and represents a dispersion degree of the material.

[0091] Distortion (distortion), also referred to as distortion, is a degree at which an image formed by the optical system for an object is distorted relative to the object. Distortion is caused because a height of a point at which chief rays with different fields of view intersect a Gaussian imaging plane after the chief rays pass through the optical system is not equal to an ideal imaging height due to an impact of stop spherical aberration, and a difference between the two heights is distortion. Therefore, distortion only changes an imaging position of an off-axis object point on an ideal plane, so that a shape of an image is distorted, but definition of the image is not affected.

[0092] TV distortion (TV distortion) is relative distortion, namely, a degree at which an actual image is deformed.

[0093] TDT represents a maximum value of TV distortion in an imaging range of the optical lens.

[0094] ImagH (imaging height) represents a half diagonal length of an effective pixel region on a photosensitive chip, namely, an imaging height on the imaging plane.

[0095] A chief ray (a chief light beam) is emitted from an edge of an object, passes through a center of an aperture stop, and finally reaches an edge of an image.

[0096] For a meridian plane, a plane formed by the chief ray (the chief light beam) from the object point off the optical axis and the optical axis is referred to as the meridian plane.

[0097] For a sagittal plane, a plane that passes through the chief ray (the chief light beam) from the object point off the optical axis and is perpendicular to the meridian plane is referred to as the sagittal plane.

[0098] First, the following specifically describes specific structures of an electronic device, a camera module, and an optical lens with reference to related accompanying drawings.

[0099] FIG. 1 is a schematic diagram of a structure of an electronic device according to an embodiment of this application. An electronic device 100 may be a mobile phone, a tablet computer (tablet personal computer), a laptop computer (laptop computer), a personal digital assistant (personal digital assistant, PDA), a camera, a personal computer, a notebook computer, a vehicle-mounted device, a wearable device, augmented reality (augmented reality, AR) glasses, an AR helmet, virtual reality (virtual reality, VR) glasses, a VR helmet, or another form of device with a photographing function. The electronic device 100 in the embodiment shown in FIG. 1 is described by using the mobile phone as an example.

[0100] With reference to FIG. 1, FIG. 2 is a partial schematic exploded view of the electronic device shown in FIG. 1. The electronic device 100 includes a screen 10, a housing 20, a host circuit board 30, and a camera module 40. It may be understood that FIG. 1 and FIG. 2 schematically show only some components included in the electronic device 100. Actual shapes, actual sizes, actual positions, and actual structures of these components are not limited in FIG. 1 and FIG. 2. In addition, when the electronic device 100 is another form of device, the electronic device 100 may not include the screen 20 and the host circuit board 30.

[0101] The screen 10 may be configured to display an image, a text, or the like. The screen 10 may be a flat screen, or may be a curved screen. In addition, the screen 10 includes a protection cover 11 and a display screen 12. The protection cover 11 is stacked on the display screen 12. The protection cover 11 may be disposed against the display screen 12, and may be mainly configured to protect the display screen 12 and protect against dust. A material of the protection cover 11 may be but is not limited to glass. The display screen 12 may be an organic light-emitting diode (organic light-emitting diode, OLED) display screen, an active-matrix organic light-emitting diode (active-matrix organic light-emitting diode, AMOLED) display screen, a quantum dot light-emitting diode (quantum dot light emitting diodes, QLED) display screen, or the like.

[0102] The housing 20 may be configured to support the screen 10. The housing 20 includes a frame 21 and a rear cover 22. The rear cover 22 and the screen 10 are respectively mounted on two opposite sides of the frame 21. In this case, the rear cover 22, the frame 21, and the screen 10 jointly surround the interior of the electronic device 100. The interior of the electronic device 100 may be configured to place a component of the electronic device 100, for example, a battery, a telephone receiver, and a microphone.

[0103] In an implementation, the rear cover 22 is fixedly connected to the frame 21 by using adhesive. In another implementation, the rear cover 22 and the frame 21 form an integral structure, namely, the rear cover 22 and the frame 21 are an integral structure.

[0104] Referring to FIG. 2 again, with reference to FIG. 1, the rear cover 22 has a light transmission member 23. The light transmission member 23 can enable ambient light to enter the interior of the electronic device 100. A shape of the light transmission member 23 is not limited to a circle shown in FIG. 1 and FIG. 2. For example, the shape of the light transmission member 23 may be an ellipse or an irregular shape.

[0105] FIG. 3 is a partial schematic cross-sectional diagram of the electronic device shown in FIG. 1 at a line A-A. The light transmission member 23 of the rear cover 22 is a through hole. The through hole communicates the interior of the electronic device 100 with the exterior of the electronic device 100. In addition, the electronic device 100 further includes a camera decoration member 51 and a cover 52. A part of the camera decoration member 51 may be fastened on an inner surface of the rear cover 22. A part of the camera decoration member 51 is in contact with a hole wall of the through hole. In addition, the cover 52 is fixedly connected to an inner surface of the camera decoration member 51. The cover 52 may prevent external water or dust from entering the interior of the electronic device 100. The cover 52 may be made of a glass material or plastic. FIG. 3 shows a disposition manner of the light transmission member 23. Certainly, the light transmission member 23 may be disposed in another manner. For example, a material of the rear cover 22 is a transparent material. A part of the rear cover 22 forms the light transmission member 23.

[0106] Referring to FIG. 3 again, with reference to FIG. 2, the host circuit board 30 is mounted inside the electronic device 100. The host circuit board 30 may be configured to mount an electronic component of the electronic device 100. For example, the electronic component may include a central processing unit (central processing unit, CPU), a memory, a battery management unit, or an image processor.

[0107] In addition, the host circuit board 30 may be a hard circuit board, may be a flexible circuit board, or may be a combination of a hard circuit board and a flexible circuit board. In addition, the host circuit board 30 may be an FR-4 dielectric board, may be a Rogers (Rogers) dielectric board, may be a dielectric board combining FR-4 and the Rogers, or the like. Herein, FR-4 is a grade designation for a flame-resistant material, and the Rogers dielectric board is a high frequency board.

[0108] Referring to FIG. 3 again, with reference to FIG. 2, the camera module 40 is fastened inside the electronic device 100. FIG. 3 shows that the camera module 40 is fastened on a surface of the screen 10 that faces the rear cover 22. In another implementation, the housing 20 may include a middle plate. The middle plate is connected to an inner surface of the frame 21, and the middle plate is located between the screen 10 and the rear cover 22. In this case, the camera module 40 may be fastened on a surface of the middle plate that faces the rear cover 22.

[0109] In addition, a quantity of camera modules 40 is not limited to one shown in FIG. 1 to FIG. 3. There may be two or more camera modules 40. In addition, when there are two or more camera modules 40, the two or more camera modules 40 may be integrated into one camera component. In addition, the camera module 40 may be but is not limited to an autofocus (autofocus, AF) camera module or a fixed-focus (fix focus, FF) camera module. The camera module 40 in this embodiment is described by using the fixed-focus camera module as an example.

[0110] In this embodiment, the camera module 40 is electrically connected to the host circuit board 30. In this case, the electronic component (for example, the processor) on the host circuit board 30 can send a signal to the camera module 40 to control the camera module 40 to photograph an image or a video. In another embodiment, when no host circuit board 30 is disposed in the electronic device 100, the camera module 40 may directly receive a signal, and perform photographing based on the signal.

[0111] With reference to FIG. 3, FIG. 4 is a schematic exploded view of a camera module of the electronic device shown in FIG. 1. The camera module 40 includes a module circuit board 41, a photosensitive chip 42, a support 43, a filter 44, an optical lens 45, and a housing 46.

[0112] The module circuit board 41 may be fastened on the surface of the screen 10 that faces the rear cover 22. In another embodiment, when the housing 20 includes the middle plate, the module circuit board 41 may be fastened on the surface of the middle plate that faces the rear cover 22.

[0113] In addition, the module circuit board 41 is electrically connected to the host circuit board 30. In this way, a signal can be transmitted between the host circuit board 30 and the module circuit board 41.

[0114] The photosensitive chip 42 is fastened to the module circuit board 41, and is electrically connected to the module circuit board 41.

[0115] In an implementation, the photosensitive chip 42 may be mounted on the module circuit board 41 by using a chip on board (chip on board, COB) technology. In another implementation, the photosensitive chip 42 may be packaged on the module circuit board 41 by using a ball grid array (ball grid array, BGA) technology or a land grid array (land grid array, LGA) technology.

[0116] In another implementation, an electronic component or a chip (for example, a drive chip) may be further mounted on the module circuit board 41. The electronic component or the chip is fastened to a periphery of the photosensitive chip 42. The electronic component or the chip may be configured to assist the photosensitive chip 42 in collecting ambient light.

[0117] The support 43 is fastened to the module circuit board 41, and is located on a same side of the module circuit board 41 as the photosensitive chip 42. A light transmission hole 431 is disposed on the support 43. The photosensitive chip 42 may be located in the light transmission hole 431. The photosensitive chip 42 may collect ambient light that passes through the light transmission hole 431.

[0118] In addition, the filter 44 is fastened to the support 43, and the filter 44 may be located in the light transmission hole 431. The filter 44 is configured to: filter out stray light in the ambient light, and project the filtered ambient light to the photosensitive chip 42, to ensure that an image photographed by the electronic device 100 has good definition. The filter 44 may be but is not limited to a blue glass filter. For example, the filter 44 may be a reflective infrared filter or a dual-passband filter (the dual-passband filter may allow visible light and infrared light in the ambient light to simultaneously pass through, allow visible light and light of another specified wavelength (for example, ultraviolet light) in the ambient light to simultaneously pass through, or allow infrared light and light of another specified wavelength (for example, ultraviolet light) to simultaneously pass through).

[0119] Referring to FIG. 4, with reference to FIG. 3, the housing 46 is fastened on a surface of the support 43 that faces away from the module circuit board 43. The housing 46 may be configured to be fixedly connected to the optical lens 45, and may be further configured to protect the optical lens 45.

[0120] In addition, the optical lens 45 is fastened on an inner side of the housing 46. FIG. 3 shows that the optical lens 45 is partially located in a region surrounded by the housing 46, and partially protrudes from the housing 46. In another embodiment, the optical lens 45 may be all located in the region surrounded by the housing 46.

[0121] The foregoing specifically describes structures of related components of the camera module 40. The following specifically describes a structure and setting of related optical parameters of the optical lens 46 with reference to the accompanying drawings.

[0122] FIG. 5 is a schematic structural diagram of an optical lens of the camera module shown in FIG. 4. The optical lens 45 includes a lens barrel 450, and a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the second lens 452, the third lens 453, the fourth lens 454, the fifth lens 455, and the sixth lens 456 are sequentially mounted in the lens barrel 450. In another implementation, the optical lens 45 may not include the lens barrel 450. The first lens 451 to the sixth lens 456 may be mounted in the housing 46 of the camera module 40.

[0123] In addition, the optical lens 45 in this embodiment further includes a stop 457. The stop 457 is located between every two lenses. The stop may be an aperture stop, and the aperture stop is configured to limit an amount of admitted light to change imaging brightness. A position of the stop is not limited to the stop that is shown in FIG. 5 and that is between the second lens 452 and the third lens 453. It may be understood that, when the stop 457 is located between the second lens 452 and the third lens 453, the stop 457 can properly allocate functions of the first lens 451 to the sixth lens 456. For example, the first lens 451 and the second lens 452 can be configured to receive light with a large field of view to a large degree, and the third lens 453 to the sixth lens 456 can be configured to correct aberration. In this case, the optical lens 45 in this implementation has a small quantity of lenses configured to enlarge the field of view. This helps simplify a structure of the optical lens 45. In addition, the optical lens 45 in this implementation has a large quantity of lenses configured to correct aberration. This helps obtain good imaging quality. In addition, when the stop 457 is located between the second lens 452 and the third lens 453, this helps correct aberration of the stop 457.

[0124] In another implementation, the optical lens 45 may not include the stop. It may be understood that FIG. 5 schematically shows only some components of the optical lens 45. Actual shapes, actual sizes, and actual structures of these components are not limited in FIG. 5.

[0125] In this embodiment, the first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power.

[0126] The sixth lens 456 may have positive focal power, or may have negative focal power. In this way, focal power of the first lens 451 to the sixth lens 456 is set, so that when the optical lens 45 can implement good imaging quality, the field of view of the optical lens 45 can be increased to a large degree to implement ultra-wide-angle setting of the optical lens 45.

[0127] In an implementation, the first lens 451 can be configured to enlarge the field of view of the optical lens 45, so that light with a large field of view enters the optical lens 45. The second lens 452 can cooperate with the first lens 451, so that large-angle light is converged on the photosensitive chip 42 to increase the field of view of the optical lens 45. In addition, the third lens 453 and the fourth lens 454 can be configured to reduce a divergence angle of light. In addition, the third lens 453 and the fourth lens 454 can be further configured to correct aberration of the optical lens 45. The fifth lens 455 can be configured to perform beam expansion on light to increase an imaging height on an imaging plane formed on the photosensitive chip 42. The sixth lens 456 is configured to correct field curvature and astigmatism in imaging by the optical lens 45, to ensure good imaging quality of the optical lens 45.

[0128] In this implementation, object side surfaces and image side surfaces of the first lens 451 to the sixth lens 456 include at least one anamorphic aspherical surface. In other words, at least one surface in the object side surface of the first lens 451, the image side surface of the first lens 451, the object side surface of the second lens 452, the image side surface of the second lens 452, . . . , and the image side surface of the sixth lens 456 is an anamorphic aspherical surface. In this implementation, that an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces is used as an example for description. It should be noted that in this embodiment, when a lens is used as a boundary, a side on which a photographed object is located is an object side, and a surface of the lens that faces the object side may be referred to as an object side surface; and when a lens is used as a boundary, a side on which an image of a photographed object is located is an image side, and a surface of the lens that faces the image side may be referred to as an image side surface.

[0129] It may be understood that, as the field of view of the optical lens is increased, imaging distortion of the optical lens becomes more obvious. For example, when the field of view of the optical lens reaches 100°, imaging distortion of the optical lens has been greater than 10%. For ultra-wide-angle setting of the optical lens, imaging distortion of the optical lens is more obvious, and imaging quality is poorer. In this implementation, at least one anamorphic aspherical surface is disposed in the lenses of the optical lens 45 that implements an ultra-wide-angle design.

[0130] Therefore, a design degree of freedom of an optical system is improved. In addition, imaging quality of the optical lens can be optimized and distortion of the optical lens can be corrected by using asymmetry of a free region, so that good imaging quality of the optical lens is ensured.

[0131] Therefore, the optical lens 45 in this implementation can implement ultra-wide-angle photographing, and can also resolve a distortion problem in ultra-wide-angle imaging to a large degree. In other words, in this implementation, the ultra-wide-angle optical lens 45 with small imaging distortion is designed.

[0132] In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0133] The anamorphic aspherical surface meets the following formulas:

[00001]$$\begin{gathered} z\left(x,y\right)=\frac{c{r}^2}{1+\sqrt{1-\left(1+K\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}^i \\ \underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0 \\ +A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16} \end{gathered}$$

[0134] A coordinate system is established by using a geometric center of the sixth lens 456 as an origin O. An optical axis direction of the sixth lens 456 is a Z-axis, a direction located on a sagittal plane of the sixth lens 456 and perpendicular to an optical axis is an X-axis, and a direction located on a meridional plane of the sixth lens 456 and perpendicular to the optical axis is a Y-axis, where z (x, y) is a vector height parallel to the Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant.

[0135] It may be understood that, it can be determined, by using the foregoing relation, that the object side surface 4561 and the image side surface 4562 of the sixth lens 456 in this embodiment are anamorphic aspherical surfaces.

[0136] In addition, remaining lenses other than the sixth lens 456 in the first lens 451 to the sixth lens 456 are non-anamorphic lenses. In this embodiment, an example in which the first lens 451 to the fifth lens 455 are non-anamorphic lenses is used for description. Both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces, both the object side surface and the image side surface are non-anamorphic spherical surfaces, or one of the object side surface and the image side surface is a non-anamorphic aspherical surface, or the other is a non-anamorphic spherical surface. In this embodiment, an example in which both the object side surface and the image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces is used for description. It may be understood that the non-anamorphic aspherical surface has a high degree of freedom. Therefore, in this embodiment, the non-anamorphic lens of the optical lens 45 may be designed based on an actual requirement, to improve aberration at different positions in a targeted manner, so as to improve imaging quality.

[0137] The non-anamorphic aspherical surface of the non-anamorphic lens in this embodiment meets the following formula:

[00002]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0138] A coordinate system is established by using a geometric center of the non-anamorphic lens as an origin O. An optical axis direction of the non-anamorphic lens is a Z-axis, a direction located on a sagittal plane of the non-anamorphic lens and perpendicular to an optical axis is an X-axis, and a direction located on a meridional plane of the non-anamorphic lens and perpendicular to the optical axis is a Y-axis, where z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is an aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0139] It may be understood that, it can be determined, by using the foregoing relation, that the object side surfaces and the image side surfaces of the first lens 451 to the fifth lens 455 are non-anamorphic aspherical surfaces.

[0140] In an implementation, FIG. 6 is schematic planar diagram of an object side surface 4561 of a sixth lens 456 of the optical lens shown in FIG. 5, and FIG. 7 is a schematic cross-sectional diagram of the sixth lens 456 shown in FIG. 6 on a sagittal plane. The coordinate system is established by using the geometric center of the sixth lens 456 as the origin O. The optical axis direction of the sixth lens 456 is the Z-axis, the direction located on the sagittal plane of the sixth lens 456 and perpendicular to the optical axis is the X-axis, and the direction located on the meridional plane of the sixth lens 456 and perpendicular to the optical axis is the Y-axis. In this way, the meridional plane of the sixth lens 456 is a YOZ plane in the coordinate system, and the sagittal plane of the sixth lens 456 is an XOZ plane in the coordinate system.

[0141] The object side surface 4561 of the sixth lens 456 includes an optical effective region 4563 and a non-optical effective region 4564 connected to the optical effective region 4563. The optical effective region 4563 and the non-optical effective region 4564 are distinguished from each other by using a dashed line in both FIG. 6 and FIG. 7. In addition, the non-optical effective region 4564 of the object side surface 4561 is marked in both a positive direction and a negative direction of the X-axis in FIG. 7. The optical effective region 4563 is a region that is of the object side surface 4561 and through which light can pass. The non-optical effective region 4564 is a region that is of the object side surface 4561 and through which light cannot pass. The non-optical effective region 4564 of the object side surface 4561 may be configured to be fastened to the lens barrel 450.

[0142] In addition, the sixth lens 456 includes a first vertex M1 and a second vertex M2. The vertex is a highest point or a lowest point on the object side surface 4561 of the sixth lens 456. In this implementation, both the first vertex M1 and the second vertex M2 are lowest points on the object side surface 4561 of the sixth lens 456. In another implementation, both the first vertex M1 and the second vertex M2 may be highest points on the object side surface 4561 of the sixth lens 456. In addition, FIG. 6 schematically shows the first vertex M1 and the second vertex M2 by using a bold dot. However, shapes, sizes, and positions of the first vertex M1 and the second vertex M2 are not limited to shapes, sizes, and positions shown in FIG. 6.

[0143] In addition, the first vertex M1 and the second vertex M2 are both located on the object side surface 4561 of the sixth lens 456, and are both located in the optical effective region 4563 of the object side surface 4561. In addition, the first vertex M1 and the second vertex M2 are both located on the XOZ plane (namely, the sagittal plane of the sixth lens 456). The first vertex M1 and the second vertex M2 are symmetric with respect to the YOZ plane (namely, the meridian plane of the sixth lens 456).

[0144] Referring to FIG. 7, a distance d1 from the first vertex M1 to a first reference plane P1 is equal to a distance d2 from the second vertex M2 to the first reference plane P1. The first reference plane P1 is perpendicular to the Z-axis (namely, an optical axis of the optical lens 45), and a point at which the Z-axis intersects the object side surface 4561 is located on the first reference plane P1.

[0145] It may be understood that the first vertex M1 and the second vertex M2 are symmetric with respect to the YOZ plane, and the distance d1 from the first vertex M1 to the first reference plane P1 is equal to the distance d2 from the second vertex M2 to the first reference plane P1. Therefore, the optical lens 45 can implement a better correction effect, and obtain high-quality imaging.

[0146] Referring to FIG. 6 again, FIG. 8 is a schematic cross-sectional diagram of the sixth lens 456 shown in FIG. 6 on a meridional plane. The sixth lens 456 includes a third vertex M3 and a fourth vertex M4. In this implementation, both the third vertex M3 and the fourth vertex M4 are highest points on the object side surface 4561 of the sixth lens 456. In another implementation, both the third vertex M3 and the fourth vertex M4 may be lowest points on the object side surface 4561 of the sixth lens 456. In addition, FIG. 6 schematically shows the third vertex M3 and the fourth vertex M4 by using a bold dot. However, shapes, positions, and sizes of the third vertex M3 and the fourth vertex M4 are not limited to shapes, positions, and sizes shown in FIG. 6.

[0147] In addition, the third vertex M3, the fourth vertex M4, the first vertex M1, and the second vertex M2 are all located on the object side surface 4561 of the sixth lens 456, and are located in the optical effective region 4563 of the object side surface 4561. The third vertex M3 and the fourth vertex M4 are located on the YOZ plane. In addition, the third vertex M3 and the fourth vertex M4 are symmetric with respect to the XOZ plane.

[0148] Referring to FIG. 8 again, a distance d3 from the third vertex M3 to the first reference plane P1 is equal to a distance d4 from the fourth vertex M4 to the first reference plane P1.

[0149] It may be understood that the third vertex M3 and the fourth vertex M4 are symmetric with respect to the XOZ plane, and the distance d3 from the third vertex M3 to the first reference plane P1 is equal to the distance d4 from the fourth vertex M4 to the first reference plane P1. Therefore, the optical lens 45 can implement a better correction effect, and obtain high-quality imaging.

[0150] With reference to FIG. 7, FIG. 9 is a schematic planar diagram of an image side surface 4562 of a sixth lens 456 of the optical lens shown in FIG. 6. The image side surface 4562 of the sixth lens 456 includes an optical effective region 4565 and a non-optical effective region 4566 connected to the optical effective region 4565. The optical effective region 4565 of the image side surface 4562 and the non-optical effective region 4566 of the image side surface 4562 are distinguished from each other by using a dashed line in both FIG. 9 and FIG. 7. In addition, the non-optical effective region 4566 of the image side surface 4562 is marked in both the positive direction and the negative direction of the X-axis in FIG. 7. The optical effective region 4565 of the image side surface 4562 is a region that is of the image side surface 4562 and through which light can pass. The non-optical effective region 4566 of the image side surface 4562 is a region that is of the image side surface 4562 and through which light cannot pass. The non-optical effective region 4566 of the image side surface 4562 may be configured to be fastened to the lens barrel 450.

[0151] In addition, the sixth lens 456 includes a fifth vertex N1 and a sixth vertex N2. The vertex is a highest point or a lowest point on the image side surface 4562 of the sixth lens 456. In this implementation, both the fifth vertex N1 and the sixth vertex N2 are highest points on the image side surface 4562 of the sixth lens 456. In another implementation, both the fifth vertex N1 and the sixth vertex N2 may be lowest points on the image side surface 4562 of the sixth lens 456. In addition, FIG. 9 schematically shows the fifth vertex N1 and the sixth vertex N2 by using a bold dot. However, shapes, sizes, and positions of the fifth vertex N1 and the sixth vertex N2 are not limited to shapes, sizes, and positions shown in FIG. 9.

[0152] In addition, the fifth vertex N1 and the sixth vertex N2 are both located on the image side surface 4562 of the sixth lens 456, and are both located in the optical effective region 4565 of the image side surface 4562. The fifth vertex N1 and the sixth vertex N2 are both located on the XOZ plane (namely, the sagittal plane of the sixth lens 456). In addition, the fifth vertex N1 and the sixth vertex N2 are symmetric with respect to the YOZ plane (namely, the meridian plane of the sixth lens 456).

[0153] Referring to FIG. 7, a distance d5 from the fifth vertex N1 to a second reference plane P2 is equal to a distance d6 from the sixth vertex N2 to the second reference plane P2. The second reference plane P2 is perpendicular to the Z-axis (namely, the optical axis of the optical lens 45), and a point at which the Z-axis intersects the image side surface 4562 is located on the second reference plane P2.

[0154] It may be understood that the fifth vertex N1 and the sixth vertex N2 are symmetric with respect to the YOZ plane, and the distance d5 from the fifth vertex N1 to the second reference plane P2 is equal to the distance d6 from the sixth vertex N2 to the second reference plane P2. Therefore, the optical lens 45 can implement a better correction effect, and obtain high-quality imaging.

[0155] Referring to FIG. 9 again, with reference to FIG. 8, the sixth lens 456 includes a seventh vertex N3 and an eighth vertex N4. In this implementation, both the seventh vertex N3 and the eighth vertex N4 are lowest points on the image side surface 4562 of the sixth lens 456. In another implementation, both the seventh vertex N3 and the eighth vertex N4 may be highest points on the image side surface 4562 of the sixth lens 456. In addition, FIG. 9 schematically shows the seventh vertex N3 and the eighth vertex N4 by using a bold dot. However, shapes, positions, and sizes of the seventh vertex N3 and the eighth vertex N4 are not limited to shapes, positions, and sizes shown in FIG. 9.

[0156] In addition, the seventh vertex N3, the eighth vertex N4, the fifth vertex N1, and the sixth vertex N2 are all located on the image side surface 4562 of the sixth lens 456, and are located in the optical effective region 4565 of the image side surface 4562. The seventh vertex N3 and the eighth vertex N4 are located on the YOZ plane. In addition, the seventh vertex N3 and the eighth vertex N4 are symmetric with respect to the XOZ plane.

[0157] Referring to FIG. 8 again, a distance d7 from the seventh vertex N3 to the second reference plane P2 is equal to a distance d8 from the eighth vertex N4 to the second reference plane P2.

[0158] It may be understood that the seventh vertex N3 and the eighth vertex N4 are symmetric with respect to the XOZ plane, and the distance d7 from the seventh vertex N3 to the second reference plane P2 is equal to the distance d8 from the eighth vertex N4 to the second reference plane P2. Therefore, the optical lens 45 can implement a better correction effect, and obtain high-quality imaging.

[0159] In the foregoing implementation, that the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces is used as an example for description. In another embodiment, when an object side surface and an image side surface of another lens are anamorphic aspherical surfaces, for the object side surface and the image side surface of the another lens, refer to a setting manner of the object side surface 4561 and the image side surface 4562 of the sixth lens 456. Details are not described herein again.

[0160] The foregoing specifically describes several setting manners of the object side surface 4561 and the image side surface 4562 of the sixth lens 456. The following specifically describes several setting manners of optical parameters of the optical lens 45.

[0161] In an implementation, the first lens 451 and the second lens 452 meet −0.5<f2/f1<−0.01, where f1 is a focal length of the first lens 451, and f2 is a focal length of the second lens 452. For example, f2/f1 is equal to −0.4, −0.3, −0.28, −0.21, −0.1, or −0.02.

[0162] It may be understood that, when the focal length f1 of the first lens 451 and the focal length f2 of the second lens 452 meet the foregoing relation, the first lens 451 and the second lens 452 can cooperate well, to collect light with a large field of view to a large degree and implement ultra-wide-angle setting of the optical lens 45.

[0163] Certainly, in another implementation, the focal length f1 of the first lens 451 and the focal length f2 of the second lens 452 may not meet the foregoing relation.

[0164] In an implementation, the focal length f1 of the first lens 451 and the focal length f2 of the second lens 452 meet −0.35≤f2/f1≤−0.03.

[0165] In an implementation, the third lens 453 and the fourth lens 454 meet −4<f4/f3<0, where f3 is a focal length of the third lens 453, and f4 is a focal length of the fourth lens 454. For example, f4/f3 is equal to −3.8, −3, −2.2, −2, −1.7, −1, or −0.8.

[0166] It may be understood that, when the focal length f3 of the third lens 453 and the focal length f4 of the fourth lens 454 meet the foregoing relation, the third lens 453 and the fourth lens 454 can cooperate well, so that pupil aberration in imaging by the optical lens 45 is well corrected. In addition, the third lens 453 and the fourth lens 454 can reduce a divergence angle of light passing through the second lens 452.

[0167] Certainly, in another implementation, the focal length f3 of the third lens 453 and the focal length f4 of the fourth lens 454 may not meet the foregoing relation.

[0168] In an implementation, the focal length f3 of the third lens 453 and the focal length f4 of the fourth lens 454 meet −2.5≤f4/f3<0.

[0169] In an implementation, the fifth lens 455 meets 0.1<f5/f<1.5, where f5 is a focal length of the fifth lens 455, and f is a focal length of the optical lens 45. For example, f5/f is equal to 0.2, 0.22, 0.33, 0.37, 0.5, 0.7, 0.9, 1, 1.1, 1.3, or 1.4.

[0170] It may be understood that, when the focal length f5 of the fifth lens 455 and the focal length f of the optical lens 45 meet the foregoing relation, focal power of the fifth lens 455 can be properly allocated, so that the fifth lens 455 has a good aberration correction effect.

[0171] Certainly, in another implementation, the focal length f5 of the fifth lens 455 and the focal length f of the optical lens 45 may not meet the foregoing relation.

[0172] In an implementation, the focal length f5 of the fifth lens 455 and the focal length f of the optical lens 45 meet 0.5≤f5/f≤1.

[0173] In an implementation, the fifth lens 455 and the third lens 453 meet 0<R6/R10<2.9, where R6 is a curvature radius of the image side surface of the third lens 453, and R10 is a curvature radius of the image side surface of the fifth lens 455. For example, R6/R10 is equal to 0.22, 0.31, 0.5, 0.9, 1, 1.3, 2, 2.4, 2.6, or 2.8.

[0174] It may be understood that, when the curvature radius R6 of the image side surface of the third lens 453 and the curvature radius R10 of the image side surface of the fifth lens 455 meet the foregoing relation, the third lens 453 and the fifth lens 455 can reduce a divergence angle of light as much as possible and correct system field curvature and distortion, to implement a better imaging effect.

[0175] Certainly, in another implementation, the curvature radius R6 of the image side surface of the third lens 453 and the curvature radius R10 of the image side surface of the fifth lens 455 may not meet the foregoing relation.

[0176] In an implementation, the curvature radius R6 of the image side surface of the third lens 453 and the curvature radius R10 of the image side surface of the fifth lens 455 meet 0<R6/R10≤2.

[0177] In an implementation, the fourth lens 454 and the fifth lens 455 meet −0.05<T45/f<0.4, where T45 is a distance between the fourth lens 454 and the fifth lens 455, and f is the focal length of the optical lens 45. For example, T45/f is equal to 0.06, 0.11, 0.25, 0.29, 0.3, 0.33, 0.35, 0.36, or 0.39.

[0178] It may be understood that, when the distance T45 between the fourth lens 454 and the fifth lens 455 and the focal length f of the optical lens 45 meet the foregoing relation, curvature of the object side surface of the fifth lens 455 can be well controlled. In this case, the fifth lens 455 has low manufacturing difficulty and good practicability.

[0179] Certainly, in another implementation, the distance T45 between the fourth lens 454 and the fifth lens 455 and the focal length f of the optical lens 45 may not meet the foregoing relation.

[0180] In an implementation, the distance T45 between the fourth lens 454 and the fifth lens 455 and the focal length f of the optical lens 45 meet 0.1≤T45/f≤0.3.

[0181] In an implementation, the optical lens 45 meets 0<(T23+T56)/TTL<0.5, where T23 is a distance between the second lens 452 and the third lens 453, T56 is a distance between the fifth lens 455 and the sixth lens 456, and TTL is a distance from the object side surface of the first lens 451 to an imaging plane in an optical axis direction of the optical lens 45. For example, (T23+T56)/TTL is equal to 0.02, 0.13, 0.24, 0.27, 0.3, 0.32, 0.35, 0.4, or 0.48.

[0182] It may be understood that, when the optical lens 45 meets the foregoing relation, the total track length (TTL) of the optical lens 45 can be well controlled to facilitate miniaturization setting of the optical lens 45. In addition, a system height of the optical lens 45 can also be well reduced to facilitate thinning setting of the optical lens 45.

[0183] Certainly, in another implementation, the optical lens 45 may not meet the foregoing relation.

[0184] In an implementation, the optical lens 45 meets 0<(T23+T56)/TTL≤0.3.

[0185] In an implementation, the optical lens 45 meets |TDT|≤5.0%, and TDT is a maximum value of TV distortion in an imaging range of the optical lens 45.

[0186] It may be understood that, when the optical lens 45 meets |TDT|≤5.0%, distortion of the optical lens 45 is small, and imaging quality of the optical lens 45 is good.

[0187] In an implementation, the optical lens 45 meets 100°≤FOV≤140°, and FOV is a field of view of the camera lens group. For example, FOV is equal to 100°, 103°, 112°, 126°, 135°, 136°, 137°, 138°, 139°, or 140°.

[0188] It may be understood that, when the field of view (FOV) of the optical lens 45 meets 100°≤FOV≤140°, the optical lens 45 has a large field of view, namely, ultra-wide-angle setting of the optical lens 45 is implemented.

[0189] In an implementation, the optical lens 45 meets 135°<FOV≤140°. For example, FOV is equal to 136°, 137°, 138°, 139°, or 140°.

[0190] In an implementation, the optical lens 45 meets 0<ImagH/TTL<1, where TTL is the distance from the object side surface of the first lens 451 to the imaging plane in the optical axis direction of the optical lens 45, and ImagH is a half diagonal length of an effective pixel region on the photosensitive chip 42, namely, an imaging height on the imaging plane. For example, ImagH/TTL is equal to 0.1, 0.22, 0.34, 0.45, 0.52, 0.66, 0.81, or 0.97.

[0191] It may be understood that, when the optical lens 45 meets the foregoing relation, the imaging height on the imaging plane of the optical lens 45 is large, namely, imaging quality of the optical lens 45 is good. In addition, the total track length of the optical lens 45 is small. This facilitates application to a thin electronic device such as a mobile phone or a tablet.

[0192] In an implementation, each lens of the optical lens 45 may be made of a plastic material, a glass material, or another composite material. The plastic material can be used to easily produce various lens structures with complex shapes. A refractive index n1 of a lens of the glass material meets 1.50≤n1≤1.90. The refractive index can be selected from a wider range than a refractive index of a plastic lens with a range (1.55 to 1.65). Therefore, a thin but better-performance glass lens is more easily obtained, this helps reduce on-axis thicknesses of a plurality of lenses of the optical lens 45, and a lens structure with a complex shape is not easily produced. Therefore, in some implementations of this application, production costs, efficiency, and optical effects are considered, and specific application materials of different lenses are properly used based on a requirement.

[0193] The following describes in more detail some specific but non-limiting examples in the implementations of this application with reference to related accompanying drawings.

[0194] Implementation 1: FIG. 10 is a schematic structural diagram of an implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has negative focal power.

[0195] In this implementation, both an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 10 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0196] Design parameters of the optical lens 45 in Implementation 1 of this application are shown in the following Table 1.

TABLE-US-00001 TABLE 1 Design parameters of an optical lens 45 in Implementation 1 Material Sur- Re- face Cur- frac- Abbe Conic num- Surface vature Thick- tive num- Focal coef- ber type radius ness index ber length ficient OBJ Spher- Infi- Infi- ical nite nite surface S1 Aspher-  9.000 0.500 1.661 20.365  50.491   0 ical surface S2 Aspher- 12.000 0.100   0 ical surface S3 Aspher-  5.902 1.075 1.923 20.881 −11.413   0 ical surface S4 Aspher-  3.434 0.843   0 ical surface STOP Spher- 0.066   0 ical surface S5 Aspher- 49.999 2.350 1.544 55.865   4.053   3.203 ical surface S6 Aspher- −2.280 0.500  −0.274 ical surface S7 Aspher-  5.049 0.709 1.661 20.365  −8.241  −0.280 ical surface S8 Aspher-  2.496 0.862  −9.511 ical surface S9 Aspher- −3.285 2.100 1.544 55.865   3.345  −1.984 ical surface S10 Aspher- −1.440 0.100  −3.668 ical surface S11 Aspher-  9.170 1.896 1.544 55.865  −8.868  −8.878 (AAS) ical surface S12 Aspher-  2.939 0.813 −46.201 (AAS) ical surface S13 Spher- Infi- 0.210 1.517 64.167 ical nite surface S14 Spher- Infi- 0.449 ical nite surface

[0197] OBJ (English full name: object) represents an object surface. S1 represents the object side surface of the first lens 451. S2 represents the image side surface of the first lens 451. S3 represents the object side surface of the second lens 452. S4 represents the image side surface of the second lens 452. S5 represents the object side surface of the third lens 453. S6 represents the image side surface of the third lens 453. S7 represents the object side surface of the fourth lens 454. S8 represents the image side surface of the fourth lens 454. S9 represents the object side surface of the fifth lens 455. S10 represents the image side surface of the fifth lens 455. S11 represents the object side surface of the sixth lens 456. AAS (anamorphic aspherical surface) is an anamorphic aspherical surface. Therefore, S11 (AAS) indicates that the object side surface of the sixth lens 456 is an anamorphic aspherical surface. S12 represents the image side surface of the sixth lens 456. S12 (AAS) indicates that the image side surface of the sixth lens 456 is an anamorphic aspherical surface. S13 represents an object side surface of the filter 44. S14 represents an image side surface of the filter 44. STOP represents the stop 457. It should be noted that in this application, symbols such as OBJ, S1, S2, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S13, S14, AAS, and STOP represent same meanings, and are not described again when the symbols appear below again.

[0198] In addition, a thickness of S1 is a distance between the object side surface of the first lens 451 and the image side surface of the first lens 451. A thickness of S2 is a distance between the image side surface of the first lens 451 and the object side surface of the second lens 452. A thickness of S3 is a distance between the object side surface of the second lens 452 and the image side surface of the second lens 452. A thickness of S4 is a distance between the image side surface of the second lens 452 and the stop. A thickness of the stop is a distance between the stop and the third lens 453. A thickness of S5 is a distance between the object side surface of the third lens 453 and the image side surface of the third lens 453. A thickness of S6 is a distance between the image side surface of the third lens 453 and the object side surface of the fourth lens 454. A thickness of S7 is a distance between the object side surface of the fourth lens 454 and the image side surface of the fourth lens 454. A thickness of S8 is a distance between the image side surface of the fourth lens 451 and the object side surface of the fifth lens 455. A thickness of S9 is a distance between the object side surface of the fifth lens 455 and the image side surface of the fifth lens 455. A thickness of S10 is a distance between the image side surface of the fifth lens 455 and the object side surface of the sixth lens 456. A thickness of S11 is a distance between the object side surface of the sixth lens 456 and the image side surface of the sixth lens 456. A thickness of S12 is a distance between the image side surface of the sixth lens 456 and the object side surface of the filter 44. A thickness of S13 is a distance between the object side surface of the filter 44 and the image side surface of the filter 44. A thickness of S14 is a distance between the image side surface of the filter 44 and an imaging plane. It should be noted that in this application, when the foregoing symbols appear in the following tables again, the symbols represent same meanings, and not described again.

[0199] Based on the data in Table 1, the design parameters of the optical lens 45 in Implementation 1 of this application may be obtained, and are shown in Table 2.

TABLE-US-00002 TABLE 2 Design parameters of an optical lens 45 in Implementation 1 f1 (mm) 50.491 f4 (mm) −8.241 f2 (mm) −11.143 f5 (mm) 3.345 f3 (mm) 4.053 f6 (mm) −8.868 f(mm) 4.18 |f1/f| 12.078 |f2/f| 2.665 |f3/f| 0.969 |f4/f| 1.971 |f5/f| 0.8 |f6/f| 2.121 f2/f1 −0.221 f4/f3 −2.033 FOV (°) 104 f/EPD 2.05 T45/f 0.243 ImagH (mm) 4.46 TTL (mm) 12.653 ImagH/TTL 0.352 (T23 + T56)/TTL 0.019 R6/R10 1.583 Fno 2.05

[0200] In the foregoing table, f1 represents a focal length of the first lens 451, f2 represents a focal length of the second lens 452, f3 represents a focal length of the third lens 453, f4 represents a focal length of the fourth lens 454, f5 represents a focal length of the fifth lens 455, f6 represents a focal length of the sixth lens 456, f represents a focal length of the optical lens 45, FOV is a field of view of the optical lens 45, EPD represents an entrance pupil diameter of the optical lens 45, T45 represents a distance between the fourth lens 454 and the fifth lens 455, ImagH represents a half diagonal length of an effective pixel region on the photosensitive chip 42, namely, an imaging height on the imaging plane, TTL represents a total track length of the optical lens 45, T23 is a distance between the second lens 452 and the third lens 453, T56 is a distance between the fifth lens 455 and the sixth lens 456, R6 is a curvature radius of the image side surface of the third lens 453, R10 is a curvature radius of the image side surface of the fifth lens 455, and Fno is an F-number of the optical lens 45. It should be noted that in this application, symbols such as f1, f2, f3, f4, f5, f6, f, EPD, T45, ImagH, TTL, T23, T56, R6, R10, Fno, and FOV represent same meanings, and are not described again when the symbols appear below again.

[0201] It may be learned from Table 2 that the field of view (FOV) of the optical lens 45 is 104° and the F-number (Fno) is 2.05. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture (it may be understood that a smaller F-number (Fno) indicates a wider aperture), and can better meet a photographing requirement. In addition, TTL is 12.653 mm, ImagH is 4.46 mm, and ImagH/TTL=0.352. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length (TTL) of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0202] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 1 of this application are shown in the following Table 3.

TABLE-US-00003 TABLE 3 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 1 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S1 0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S2 0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S3 2.4965E−03 −5.6139E−05  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S4 7.9848E−03 −1.5913E−04  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S5 3.3387E+00 −1.2819E+00  2.9002E−01 −1.2724E−01 −1.7361E−03  3.7577E−02 −5.1035E−02 S6 3.5319E+00 −3.5425E+00 −4.4467E−01  4.1033E−01 −1.6697E−01 −1.5267E−01 −1.1400E−01 S7 2.6616E+00 −1.7635E+00  3.7925E−01 −1.8843E−02 −2.6318E−03 −6.9181E−03  2.2100E−03 S8 3.5006E+00 −1.3561E+00  3.6278E−01 −1.4376E−01 −4.0291E−02 −2.5340E−02 −1.8542E−03 S9 4.7024E+00  2.2063E+00 −1.9711E−01 −1.4412E−01  2.5364E−01 −1.6378E−02  9.2933E−03 S10 4.3924E+00  1.2783E+00  2.8222E+00 −1.1204E−01 −1.8356E−01 −2.9911E−01 −1.8144E−01

[0203] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. It should be noted that each parameter in the table is represented through scientific notation. For example, 2.4965E-03 means 2.4965×10.sup.−3, and −5.6139E-05 means −5.6139×10.sup.−5.

[0204] The foregoing parameters are substituted into the following formula:

[00003]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0205] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0206] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0207] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 1 of this application are shown in the following Table 4.

TABLE-US-00004 TABLE 4 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 1 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11  6.961E−03  1.418E−02  7.016E−03 −5.885E−04 −1.760E−03 −1.661E−03 −5.957E−04  1.332E−05 S12 −3.081E−03 −5.802E−03 −2.852E−03  2.080E−04  6.429E−04  6.514E−04  2.136E−04 −5.019E−06 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11  5.613E−05  7.766E−05  4.953E−05  1.606E−05 1.156E−07 5.566E−07 1.377E−06 1.181E−06 S12 −1.943E−05 −3.324E−05 −1.622E−05 −3.815E−06 7.750E−08 5.050E−07 7.744E−07 7.767E−07 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11  1.114E−06 1.436E−07 −7.782E−09 −3.441E−08 −9.585E−08 −1.429E−07 −1.704E−07 −7.028E−08 S12 −2.012E−07 4.490E−08  8.907E−10  2.782E−08 −5.212E−09  4.679E−08  7.789E−08  9.297E−09 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11 −9.456E−09 1.867E−10 1.447E−09  2.898E−09  5.206E−10 −8.234E−09  9.248E−09  1.020E−10 S12  6.456E−10 1.108E−10 8.786E−10 −1.279E−09 −3.189E−09 −2.776E−12 −3.636E−10 −1.112E−08 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11  1.135E−10  1.726E−11 1.321E−11  1.971E−11 −1.884E−10 −9.634E−10 −2.433E−09  1.499E−09 S12 −8.632E−11 −3.929E−12 6.581E−11 −1.365E−10 −4.042E−10 −5.594E−10 −1.174E−10 −3.156E−10 Surface sequence number A.sub.150 A.sub.152 S11 −3.730E−10 −5.362E−12 S12 −9.850E−11 −6.269E−12

[0208] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, A.sub.27, . . . , A.sub.144, A.sub.146, A.sub.150, and A.sub.152 represent polynomial coefficients. The foregoing parameters are substituted into the following formulas:

[00004]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0209] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0210] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0211] FIG. 11 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 10. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=1.6694%, and TV distortion in the imaging range of the optical lens 4510 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0212] Implementation 2: FIG. 12 is a schematic structural diagram of another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has negative focal power.

[0213] In this implementation, both an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 12 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0214] Design parameters of the optical lens 45 in Implementation 2 of this application are shown in the following Table 5.

TABLE-US-00005 TABLE 5 Design parameters of an optical lens 45 in Implementation 2 Material Sur- Re- face Cur- frac- Abbe Conic num- Surface vature Thick- tive num- Focal coef- ber type radius ness index ber length ficient OBJ Spher- Infi- Infi-   0 ical nite nite surface S1 Aspher-  9.000 0.500 1.661 20.365  40.980   0 ical surface S2 Aspher- 13.106 0.800   0 ical surface S3 Aspher-  6.163 0.500 1.923 20.881  −3.387   0 ical surface S4 Aspher- 3.162 0.897   0 ical surface STOP Spher- Infi- 0.146   0 ical nite surface S5 Aspher-  7.000 1.9 1.544 55.865   3.468   6.990 ical surface S6 Aspher- −2.350 0.475  −0.282 ical surface S7 Aspher-  5.299 0.709 1.661 20.365  −7.619  −0.331 ical surface S8 Aspher-  2.457 1.009  −9.459 ical surface S9 Aspher- −2.985 1.800 1.544 55.865   3.639  −1.971 ical surface S10 Aspher- −1.448 0.098  −3.665 ical surface S11 Aspher-  9.341 1.818 1.544 55.865 −10.446 −10.033 (AAS) ical surface S12 Aspher-  3.300 0.724 −49.970 (AAS) ical surface S13 Aspher- Infi- 0.210 1.517 64.167   0 ical nite surface S14 Spher- Infi- 0.375   0 ical nite surface

[0215] Based on the data in Table 5, the design parameters of the optical lens 45 in Implementation 2 of this application may be obtained, and are shown in Table 6.

TABLE-US-00006 TABLE 6 Design parameters of an optical lens 45 in Implementation 2 f1 (mm) 40.980 f4 (mm) −7.619 f2 (mm) −3.387 f5 (mm) 3.639 f3 (mm) 3.468 f6 (mm) −10.446 f(mm) 4.141 |f1/f| 9.897 |f2/f| 0.818 |f3/f| 0.837 |f4/f| 1.84 |f5/f| 0.879 |f6/f| 2.522 f2/f1 −0.0826 f4/f3 −2.197 FOV (°) 101 f/EPD 2.05 T45/f 0.244 ImagH (mm) 4.38 TTL (mm) 12.042 ImagH/TTL 0.364 (T23 + T56)/TTL 0.075 R6/R10 1.623 Fno 2.05

[0216] It may be learned from Table 6 that the field of view (FOV) of the optical lens 45 is 101° and the F-number (Fno) is 2.05. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In addition, TTL is 12.042 mm, ImagH is 4.38 mm, and ImagH/TTL=0.364. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length (TTL) of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0217] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 2 of this application are shown in the following Table 7.

TABLE-US-00007 TABLE 7 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 2 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S1 0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S2 0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S3 1.1577E−03 −2.4902E−04  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S4 8.1578E−03  1.6693E−04  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S5 3.6777E+00 −1.1523E+00  2.3687E−01 −1.1198E−01  1.9730E−03  2.8580E−02 −4.4142E−02 S6 3.4502E+00 −3.5990E+00 −4.4512E−01  4.2115E−01  1.6085E−01 −1.5000E−01 −1.1190E−01 S7 2.6508E+00 −1.7955E+00  3.8154E−01 −1.6180E−02  5.0310E−04 −6.1123E−03  2.1212E−03 S8 3.5078E+00 −1.3153E+00  3.4338E−01 −1.4396E−01 −3.6263E−02 −2.6597E−02 −2.7090E−03 S9 4.7247E+00  2.0221E+00 −1.8966E−01 −7.8227E−02  2.2936E−01 −5.6007E−03  8.2865E−03 S10 4.3497E+00  1.8621E+00  2.7926E+00 −1.4598E−01 −1.6696E−01 −3.0213E−01 −1.7885E−01

[0218] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00005]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0219] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0220] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0221] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 2 of this application are shown in the following Table 8.

TABLE-US-00008 TABLE 8 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 2 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11  6.525E−03  1.147E−02  6.464E−03 −6.689E−04 −1.968E−03 −1.849E−03 −6.720E−04  8.521E−06 S12 −3.495E−03 −7.210E−03 −2.938E−03  2.204E−04  5.722E−04  5.863E−04  2.813E−04 −3.646E−06 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11  4.902E−05  6.281E−05  5.181E−05  1.490E−05 −1.588E−07 5.990E−08 5.538E−07 −2.992E−07 S12 −2.252E−05 −3.668E−05 −1.763E−05 −6.184E−06  1.520E−07 3.390E−07 3.248E−07  5.834E−07 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11 −7.648E−08  5.918E−08 −1.639E−08 −6.353E−08 −1.728E−07 −3.377E−07 −7.119E−07 −6.650E−08 S12 −6.569E−07 −2.548E−08 −5.743E−09  2.580E−08 −9.782E−09 −2.418E−08  1.708E−07 −4.263E−08 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11  7.265E−09 1.792E−09 3.672E−09 −5.627E−09 −4.867E−09 −3.145E−08 −4.606E−08 −1.307E−09 S12 −6.176E−09 6.666E−12 7.938E−10 −2.804E−10 −4.515E−09  3.340E−09 −7.152E−09 −2.388E−08 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11  3.606E−10  1.754E−10 1.243E−09  5.021E−10 −1.617E−09 −1.513E−09 −8.188E−09 1.065E−08 S12 −1.050E−10 −2.789E−11 6.994E−11 −7.317E−11 −5.146E−10 −8.071E−10  7.099E−11 4.583E−10 Surface sequence number A.sub.150 A.sub.152 S11 −1.682E−09 −6.675E−11 S12  4.301E−10 −3.844E−14

[0222] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, A.sub.27, . . . , A.sub.144, A.sub.146, A.sub.150, and A.sub.152 represent polynomial coefficients. The foregoing parameters are substituted into the following formulas:

[00006]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0223] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0224] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0225] FIG. 13 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 12. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=2.3119%, and TV distortion in the imaging range of the optical lens 45 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0226] Implementation 3: FIG. 14 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has negative focal power.

[0227] In this implementation, an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 14 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0228] Design parameters of the optical lens 45 in Implementation 3 of this application are shown in the following Table 9.

TABLE-US-00009 TABLE 9 Design parameters of an optical lens 45 in Implementation 3 Material Sur- Re- face Cur- frac- Abbe Conic num- Surface vature Thick- tive num- Focal coef- ber type radius ness index ber length ficient OBJ Spher- Infi- Infi- ical nite nite surface S1 Aspher-  9.977 2.500 1.661 20.365 52.743   0.000 ical surface S2 Aspher- 12.519 0.100   0.000 ical surface S3 Aspher-  5.766 0.900 1.923 20.881 −3.478   0.000 ical surface S4 Aspher-  3.246 1.340   0.000 ical surface STOP Spher- Infi- 0.180   0.000 ical nite surface S5 Aspher- 34.549 2.082 1.544 55.865  3.817 −25.433 ical surface S6 Aspher- −2.173 0.462  −0.272 ical surface S7 Aspher-  5.100 0.587 1.661 20.365 −8.359  −0.339 ical surface S8 Aspher-  2.543 0.804  −9.749 ical surface S9 Aspher- −3.376 2.101 1.544 55.865  3.287  −2.027 ical surface S10 Aspher- −1.431 0.109  −3.701 ical surface S11 Aspher-  9.911 1.916 1.544 55.865 −6.731 −10.716 (AAS) ical surface S12 Aspher-  2.500 0.817 −37.422 (AAS) ical surface S13 Spher- Infi- 0.210 1.517 64.167   0.000 ical nite surface S14 Spher- Infi- 0.435   0.000 ical nite surface

[0229] Based on the data in Table 9, the design parameters of the optical lens 45 in Implementation 3 of this application may be obtained, and are shown in the following Table 10.

TABLE-US-00010 TABLE 10 Design parameters of an optical lens 45 in Implementation 3 f1 (mm) 52.743 f4 (mm) −8.359 f2 (mm) −3.478 f5 (mm) 3.287 f3 (mm) 3.817 f6 (mm) −6.731 f(mm) 4.21 |f1/f| 12.533 |f2/f| 0.826 |f3/f| 0.907 |f4/f| 1.986 |f5/f| 0.781 |f6/f| 1.599 f2/f1 −0.066 f4/f3 −2.190 FOV (°) 100 f/EPD 2.04 T45/f 0.191 ImagH (mm) 4.39 TTL (mm) 14.623 ImagH/TTL 0.3 (T23 + T56)/TTL 0.014 R6/R10 1.519 Fno 2.04

[0230] It may be learned from Table 10 that the field of view (FOV) of the optical lens 45 is 100° and the F-number (Fno) is 2.04. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In addition, TTL is 14.623 mm, ImagH is 4.39 mm, and ImagH/TTL=0.3. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0231] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 3 of this application are shown in the following Table 11.

TABLE-US-00011 TABLE 11 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 3 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S1 0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S2 0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S3 2.6177E−03 −7.1695E−05  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S4 6.2457E−03 −1.6474E−04  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S5 3.2414E+00 −1.0821E+00  3.2488E−01 −1.0098E−01  1.2073E−02  3.3096E−02 −3.8390E−02 S6 3.4756E+00 −3.4977E+00 −4.5751E−01  4.2179E−01  1.5905E−01 −1.4458E−01 −1.1653E−01 S7 2.6625E+00 −1.7365E+00  3.8310E−01 −1.6967E−02 −1.9119E−03 −8.0984E−03  4.4516E−03 S8 3.4896E+00 −1.3727E+00  3.6406E−01 −1.4937E−01 −4.0489E−02 −2.6909E−02 −3.0597E−03 S9 4.6950E+00  2.2273E+00 −2.0976E−01 −1.2943E−01  2.3726E−01 −8.2719E−03  1.0964E−02 S10 4.3941E+00  1.3309E+00  2.8230E+00 −1.1652E−01 −1.9823E−01 −2.9619E−01 −1.7306E−01

[0232] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00007]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0233] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0234] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0235] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 3 of this application are shown in the following Table 12.

TABLE-US-00012 TABLE 12 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 3 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11  6.795E−03  1.247E−02  6.503E−03 −6.325E−04 −1.873E−03 −1.691E−03 −6.457E−04  1.215E−05 S12 −2.434E−03 −6.007E−03 −2.630E−03  1.765E−04  5.598E−04  6.458E−04  2.607E−04 −4.606E−06 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11  5.634E−05  6.102E−05  5.037E−05  1.805E−05 3.073E−08 1.517E−06 1.759E−06 1.192E−06 S12 −2.064E−05 −3.989E−05 −2.038E−05 −3.837E−06 6.927E−08 6.103E−07 8.443E−07 2.213E−06 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11  2.025E−06  1.934E−07 −1.238E−08  4.396E−08 −5.843E−08 −1.212E−07 −4.131E−07 −3.086E−08 S12 −1.078E−06 −1.569E−07 −7.652E−10 −3.024E−08 −2.202E−08 −2.786E−08  6.549E−08  2.639E−07 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11 −1.574E−08 1.840E−10 −3.620E−09 −8.794E−10  7.125E−09 −1.500E−08  3.294E−09 −1.064E−08 S12 −3.663E−09 1.260E−10  1.678E−09 −2.082E−09 −8.195E−09  1.526E−08 −2.190E−08 −4.079E−08 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11  1.209E−10  1.020E−10 2.313E−10 −1.615E−09 −2.280E−09 −4.519E−09 −1.162E−08  8.950E−09 S12 −4.196E−11 −4.262E−12 2.656E−10  6.308E−11 −5.435E−10 −8.834E−10  4.989E−10 −1.659E−09 Surface sequence number A.sub.150 A.sub.152 S11 −3.307E−10 −1.327E−11 S12  1.028E−09  1.712E−12

[0236] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients.

[0237] The foregoing parameters are substituted into the following formulas:

[00008]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0238] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0239] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0240] FIG. 15 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 14. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=2.6506%, and TV distortion in the imaging range of the optical lens 45 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0241] Implementation 4: FIG. 16 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has negative focal power.

[0242] In this implementation, an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 16 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0243] Design parameters of the optical lens 45 in Implementation 4 of this application are shown in the following Table 13.

TABLE-US-00013 TABLE 13 Design parameters of an optical lens 45 in Implementation 4 Material Sur- Re- face Cur- frac- Abbe Conic num- Surface vature Thick- tive num- Focal coef- ber type radius ness index ber length ficient OBJ Spher- Infi- Infi- ical nite nite surface S1 Aspher-  3.500 0.995 1.923 20.881   8.635   0.000 ical surface S2 Aspher- 10.000 0.070   0.000 ical surface S3 Aspher-  7.315 0.402 1.923 20.881  −2.611   0.195 ical surface S4 Aspher-  2.437 1.112   0.011 ical surface STOP Spher- Infi- 0.445   0.000 ical nite surface S5 Aspher-  6.121 1.700 1.544 55.865   3.357   1.166 ical surface S6 Aspher- −2.363 0.599  −0.286 ical surface S7 Aspher-  5.258 0.709 1.661 20.365  −7.871  −0.413 ical surface S8 Aspher-  2.488 0.918  −9.799 ical surface S9 Aspher- −2.827 1.850 1.544 55.865   3.593  −2.229 ical surface S10 Aspher- −1.427 0.350  −3.574 ical surface S11 Aspher-  8.902 1.499 1.544 55.865 −12.052  −9.787 (AAS) ical surface S12 Aspher-  3.561 0.619 −47.872 (AAS) ical surface S13 Spher- Infi- 0.210 1.517 64.167   0.000 ical nite surface S14 Spher- Infi- 0.310   0.000 ical nite surface

[0244] Based on the data in Table 13, the design parameters of the optical lens 45 in Implementation 4 of this application may be obtained, and are shown in the following Table 14.

TABLE-US-00014 TABLE 14 Design parameters of an optical lens 45 in Implementation 4 f1 (mm) 8.635 f4 (mm) −7.871 f2 (mm) −2.611 f5 (mm) 3.593 f3 (mm) 3.357 f6 (mm) −12.052 f(mm) 4.253 |f1/f| 2.03 |f2/f| 0.614 |f3/f| 0.790 |f4/f| 1.853 |f5/f| 0.846 |f6/f| 2.837 f2/f1 −0.302 f4/f3 −2.345 FOV (°) 100 f/EPD 2.05 T45/f 0.217 ImagH (mm) 3.94 TTL (mm) 11.8684 ImagH/TTL 0.332 (T23 + T56)/TTL 0.036 R6/R10 1.657 Fno 2.05

[0245] It may be learned from Table 14 that the field of view (FOV) of the optical lens 45 is 100° and the F-number (Fno) is 2.05. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In addition, TTL is 11.8684 mm, ImagH is 3.94 mm, and ImagH/TTL=0.332. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0246] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 4 of this application are shown in the following Table 15.

TABLE-US-00015 TABLE 15 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 4 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S1  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S2  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S3 −1.4285E+00  2.0901E−01 −4.9205E−02  2.2758E−02  4.6089E−02 −3.5650E−02 −3.2758E−02 S4 −3.3642E+00 −5.2680E−01  4.3980E−01  1.5015E−01 −1.4959E−01 −8.5065E−02 −1.5040E−02 S5 −1.8300E+00  3.9127E−01  6.0647E−03  1.8752E−03 −2.6337E−03  6.2850E−03  1.5888E−03 S6 −1.1820E+00  3.1251E−01 −1.5220E−01 −4.7590E−02 −2.2504E−02 −6.7780E−04 −4.1749E−04 S7  2.2171E+00 −2.9100E−01 −5.4245E−04  1.8737E−01  1.4373E−02  1.0547E−02 −1.6012E−02 S8  1.8892E+00  2.7806E+00 −1.3519E−01 −1.7452E−01 −2.8777E−01 −1.7306E−01 −8.3124E−02 S9 −1.4285E+00  2.0901E−01 −4.9205E−02  2.2758E−02  4.6089E−02 −3.5650E−02 −3.2758E−02 S10 −3.3642E+00 −5.2680E−01  4.3980E−01  1.5015E−01 −1.4959E−01 −8.5065E−02 −1.5040E−02

[0247] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00009]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0248] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0249] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0250] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 4 of this application are shown in the following Table 16.

TABLE-US-00016 TABLE 16 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 4 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11  6.219E−03  1.103E−02  5.476E−03 −8.654E−04 −2.194E−03 −2.085E−03 −8.524E−04  1.063E−05 S12 −3.862E−03 −9.936E−03 −3.680E−03  1.887E−04  5.392E−04  3.472E−04  2.101E−04 −3.883E−06 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11 −1.261E−05 −4.330E−05 −3.504E−05  2.095E−05 −1.558E−07 9.369E−07 1.821E−06 −9.500E−06 S12 −2.545E−05 −3.298E−05 −2.044E−05 −4.979E−06  1.523E−07 8.506E−07 3.874E−07  1.887E−06 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11  1.205E−06  1.148E−07 −5.020E−08 −5.210E−08 −5.677E−08  8.061E−07 −1.642E−06 5.914E−07 S12 −8.046E−07 −3.798E−10 −1.091E−08  2.128E−08 −1.256E−08 −5.110E−08  4.262E−07 1.518E−07 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11  2.990E−08 −4.684E−10 −6.861E−09 7.587E−09  6.878E−08 −8.035E−08 −1.041E−07  4.128E−08 S12 −8.082E−09 −3.077E−10 −1.761E−09 1.056E−09 −3.812E−09  6.110E−10 −5.880E−09 −5.891E−08 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11  3.238E−09  1.362E−10 4.453E−10 −3.254E−09  1.455E−09  7.965E−09 −1.004E−08  3.055E−08 S12 −4.918E−10 −6.174E−11 1.533E−11  1.424E−10 −5.692E−11 −1.353E−09  3.695E−11 −5.059E−10 Surface sequence number A.sub.150 A.sub.152 S11 −1.268E−08 −2.400E−10 S12 −1.190E−09  2.102E−11

[0251] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients.

[0252] The foregoing parameters are substituted into the following formula:

[00010]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0253] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0254] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0255] FIG. 17 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 16. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=2.8277%, and TV distortion in the imaging range of the optical lens 45 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0256] Implementation 5: FIG. 18 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 465 has negative focal power.

[0257] In this implementation, an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 18 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0258] Design parameters of the optical lens 45 in Implementation 5 of this application are shown in the following Table 17.

TABLE-US-00017 TABLE 17 Design parameters of an optical lens 45 in Implementation 5 Material Sur- Re- face Cur- frac- Abbe Conic num- Surface vature Thick- tive num- Focal coef- ber type radius ness index ber length ficient OBJ Spher- Infi- Infi- ical nite nite surface S1 Aspher-  7.781 0.900 1.923 20.881  55.415   0.000 ical surface S2 Aspher-  9.772 0.150   0.000 ical surface S3 Aspher- 10.785 0.501 1.923 20.881  −3.767   0.000 ical surface S4 Aspher-  3.516 0.858   0.000 ical surface STOP Spher- Infi- 0.308   0.000 ical nite surface S5 Aspher-  5.000 1.559 1.544 55.865   3.123   1.251 ical surface S6 Aspher- −2.306 0.617  −0.321 ical surface S7 Aspher-  5.053 0.728 1.661 20.365  −5.943  −0.403 ical surface S8 Aspher-  2.096 1.007  −9.880 ical surface S9 Aspher- −2.656 1.796 1.544 55.865   3.767  −2.253 ical surface S10 Aspher- −1.437 0.150  −3.562 ical surface S11 Aspher-  7.803 1.840 1.544 55.865 −12.283  −8.679 (AAS) ical surface S12 Aspher-  3.308 0.773  −48.290 (AAS) ical surface S13 Spher- Infi- 0.210 1.517 64.167   0.000 ical nite surface S14 Spher- Infi- 0.554   0.000 ical nite surface

[0259] Based on the data in Table 17, the design parameters of the optical lens 45 in Implementation 5 of this application may be obtained, and are shown in the following Table 18.

TABLE-US-00018 TABLE 18 Design parameters of an optical lens 45 in Implementation 5 f1 (mm) 55.415 f4 (mm) −5.943 f2 (mm) −3.767 f5 (mm) 3.767 f3 (mm) 3.123 f6 (mm) −12.283 f(mm) 4.175 |f1/f| 13.272 |f2/f| 0.902 |f3/f| 0.748 |f4/f| 1.423 |f5/f| 0.902 |f6/f| 2.942 f2/f1 −0.068 f4/f3 −1.903 FOV (°) 101 f/EPD 2.05 T45/f 0.241 ImagH (mm) 4.25 TTL (mm) 12.031 ImagH/TTL 0.354 (T23 + T56)/TTL 0.084 R6/R10 1.605 Fno 2.05

[0260] It may be learned from Table 18 that the field of view (FOV) of the optical lens 45 is 101° and the F-number (Fno) is 2.05. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In addition, TTL is 12.031 mm, ImagH is 4.25 mm, and ImagH/TTL=0.354. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0261] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 5 of this application are shown in the following Table 19.

TABLE-US-00019 TABLE 19 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 5 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S1  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S2  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S3 −4.7136E−05 −4.6581E−04  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S4  1.0699E−02 −3.3017E−04  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00  0.0000E+00 S5 −1.5734E+00  2.4840E−01 −9.3049E−02 −7.3303E−03  2.5035E−02 −3.1238E−02 −2.8120E−02 S6 −3.3124E+00 −4.9982E−01  4.4351E−01  1.4851E−01 −1.4865E−01 −9.9596E−02 −2.3765E−02 S7 −1.8541E+00  3.9796E−01  2.6770E−03  5.7753E−04 −2.0272E−03  3.9776E−03  2.3068E−03 S8 −1.1514E+00  2.9622E−01 −1.5178E−01 −4.5098E−02 −2.3692E−02 −1.8388E−03  5.7623E−04 S9  2.1431E+00 −2.8161E−01 −1.8436E−02  1.8813E−01  9.9322E−03  8.9805E−03 −1.9777E−02 S10  1.9797E+00  2.7760E+00 −1.2827E−01 −1.7749E−01 −2.9102E−01 −1.7835E−01 −7.0347E−02

[0262] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00011]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0263] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0264] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0265] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 5 of this application are shown in the following Table 20.

TABLE-US-00020 TABLE 20 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 5 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11  5.611E−03  8.326E−03  4.830E−03 −7.988E−04 −2.243E−03 −2.191E−03 −9.090E−04  9.428E−06 S12 −2.052E−03 −7.944E−03 −2.246E−03  1.733E−04  4.778E−04  4.860E−04  2.248E−04 −4.908E−06 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11  3.661E−05 −5.982E−07  3.888E−05  1.963E−05 −2.189E−07 3.288E−07 1.675E−06 −6.355E−06 S12 −2.297E−05 −4.367E−05 −2.488E−05 −1.129E−05  4.971E−08 7.768E−07 5.202E−07  8.046E−07 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11  2.666E−07 1.085E−07 −9.463E−08 −2.187E−07 −2.626E−07 −5.631E−07 −9.633E−07  3.622E−07 S12 −1.237E−06 4.530E−09 −7.228E−09  1.628E−08  3.347E−08 −4.159E−08  2.756E−07 −1.847E−07 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11  1.884E−08  3.721E−11 −6.512E−09 6.857E−08 −1.190E−07 −8.687E−08 −8.202E−08  8.537E−09 S12 −1.177E−08 −1.656E−10  8.878E−10 1.583E−09 −3.704E−09 −6.559E−11 −7.922E−09 −4.147E−08 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11  2.551E−09  1.729E−10 2.023E−09 −2.865E−09 −8.300E−09 −1.286E−08 −3.110E−08 2.044E−08 S12 −2.645E−10 −1.000E−10 7.745E−12 −7.976E−12 −2.271E−10 −1.361E−09  7.617E−10 1.593E−09 Surface sequence number A.sub.150 A.sub.152 S11 −1.581E−08 −3.038E−10 S12  1.631E−09  3.553E−11

[0266] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients. The foregoing parameters are substituted into the following formulas:

[00012]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0267] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0268] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0269] FIG. 19 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 18. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=2.5481%, and TV distortion in the imaging range of the optical lens 45 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0270] Implementation 6: FIG. 20 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 465 has negative focal power.

[0271] In this implementation, an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 20 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0272] Design parameters of the optical lens 45 in Implementation 6 of this application are shown in the following Table 21.

TABLE-US-00021 TABLE 21 Design parameters of an optical lens 45 in Implementation 6 Material Surface Surface Curvature Refractive Abbe Focal Conic number type radius Thickness index number length coefficient OBJ Spherical Infinite Infinite 0.000 surface S1 Aspherical 11.866 0.700 1.544 55.865 46.254 0.000 surface S2 Aspherical 15.321 0.380 0.000 surface S3 Aspherical −3.177 0.865 1.544 55.865 −16.111 0.000 surface S4 Aspherical −5.447 0.239 0.000 surface STOP Spherical Infinite 0.000 1.251 surface S5 Aspherical 17.633 2.029 1.544 55.865 3.527 −0.321 surface S6 Aspherical −2.076 0.733 −0.403 surface S7 Aspherical 120.000 0.756 1.661 20.365 −4.222 −9.880 surface S8 Aspherical 2.877 0.494 −2.253 surface S9 Aspherical −4.792 2.174 1.544 55.865 3.066 −3.562 surface S10 Aspherical −1.441 0.056 −8.679 surface S11 Aspherical 5.212 1.511 1.544 55.865 −10.494 −48.290 (AAS) surface S12 Aspherical 2.451 0.517 0.000 (AAS) surface S13 Spherical Infinite 0.210 1.517 64.167 0.000 surface S14 Spherical Infinite 0.458 0.000 surface

[0273] Based on the data in Table 21, the design parameters of the optical lens 45 in Implementation 6 of this application may be obtained, and are shown in Table 22.

TABLE-US-00022 TABLE 22 Design parameters of an optical lens 45 in Implementation 6 f1 (mm) 46.254 f4 (mm) −4.222 f2 (mm) −16.111 f5 (mm) 3.066 f3 (mm) 3.527 f6 (mm) −10.494 f(mm) 3.646 |f1/f| 12.685 |f2/f| 4.419 |f3/f| 0.967 |f4/f| 1.158 |f5/f| 0.840 |f6/f| 2.878 f2/f1 −0.348 f4/f3 −1.254 FOV (°) 112 f/EPD 2.23 T45/f 0.136 ImagH (mm) 5.00 TTL (mm) 11.2236 ImagH/TTL 0.445 (T23 + T56)/TTL 0.026 R6/R10 1.441 Fno 2.23

[0274] It may be learned from Table 22 that the field of view (FOV) of the optical lens 45 is 112° and the F-number (Fno) is 2.23. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In this implementation, TTL is 11.2236 mm, ImagH is 5.00 mm, and ImagH/TTL=0.445. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0275] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 6 of this application are shown in the following Table 23.

TABLE-US-00023 TABLE 23 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 6 Surface number A0 A1 A2 A3 A4 A5 A6 S1 1.48E−03 1.75E−05 0.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 S2 −7.23E−03 −5.09E−04 0.00E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00 S3 3.10E+00 2.95E−02 1.74E−01 −3.88E−02 −1.67E−02 −1.64E−02 −7.39E−04 S4 4.91E+01 9.61E+00 −3.26E+00 −2.53E+00 −4.85E−01 −1.57E−02 1.95E−02 S5 7.03E−03 −3.31E−02 7.80E−03 3.08E−03 5.62E−04 −7.63E−04 −5.00E−04 S6 −5.93E−01 2.00E−02 −2.83E−02 −5.89E−03 −5.27E−03 −1.15E−03 −3.86E−04 S7 −7.55E−01 1.57E−01 −1.25E−02 −7.72E−04 −2.30E−03 −3.92E−05 5.85E−04 S8 −6.02E−01 1.63E−01 −1.84E−02 3.80E−03 −2.96E−03 −2.58E−06 1.67E−04 S9 3.69E−01 1.25E−01 −2.22E−02 −4.52E−04 −1.58E−03 1.21E−03 −2.26E−04 S10 −4.50E−01 3.08E−01 −4.72E−03 −9.14E−03 −3.34E−03 1.87E−03 5.44E−04

[0276] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00013]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0277] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0278] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0279] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 6 of this application are shown in the following Table 24.

TABLE-US-00024 TABLE 24 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 6 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11 1.58E−02 2.89E−02 1.53E−02 −3.84E−03 −9.99E−03 −1.01E−02 −3.75E−03 4.44E−04 S12 −2.98E−02 −5.12E−02 −2.87E−02 7.51E−03 2.11E−02 2.22E−02 7.14E−03 −1.21E−03 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11 1.52E−03 2.47E−03 1.60E−03 4.08E−04 −4.06E−05 −2.14E−04 −4.43E−04 −4.31E−04 S12 −4.91E−03 −7.48E−03 −4.84E−03 −1.24E−03 1.28E−04 6.47E−04 1.28E−03 1.29E−03 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11 −2.23E−04 −4.38E−05 3.07E−06 1.98E−05 4.94E−05 6.59E−05 5.02E−05 2.03E−05 S12 6.50E−04 1.28E−04 −7.88E−06 −4.72E−05 −1.18E−04 −1.58E−04 −1.16E−04 −4.78E−05 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11 3.07E−06 −1.38E−07 −8.22E−07 −2.09E−06 −4.90E−06 −4.06E−06 −2.88E−06 −5.68E−07 S12 −7.87E−06 2.55E−07 1.80E−06 5.42E−06 8.83E−06 9.10E−06 5.50E−06 1.62E−06 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.40 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11 −1.08E−07 1.03E−09 3.79E−09 −2.68E−09 8.46E−08 1.23E−07 −9.95E−10 7.46E−08 S12 2.59E−07 −3.62E−09 −3.09E−08 −8.90E−08 −1.97E−07 −2.48E−07 −1.73E−07 −1.27E−07 Surface sequence number A.sub.150 A.sub.152 S11 −4.51E−08 1.76E−09 S12 −2.96E−08 −3.17E−09

[0280] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients.

[0281] The foregoing parameters are substituted into the following formulas:

[00014]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0282] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0283] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0284] FIG. 21 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 20. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=1.5569%, and TV distortion in the imaging range of the optical lens 45 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0285] Implementation 7: FIG. 22 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has negative focal power.

[0286] In this implementation, an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 22 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0287] Design parameters of the optical lens 45 in Implementation 7 of this application are shown in the following Table 25.

TABLE-US-00025 TABLE 25 Design parameters of an optical lens 45 in Implementation 7 Material Surface Surface Curvature Refractive Abbe Focal Conic number type radius Thickness index number length coefficient OBJ Spherical Infinite Infinite 0.000 surface S1 Aspherical 5.704 0.488 1.717 47.961 38.003 0.000 surface S2 Aspherical 7.000 0.071 0.000 surface S3 Aspherical 4.902 0.799 1.923 20.881 −3.126 0.000 surface S4 Aspherical 2.917 0.925 0.000 surface STOP Spherical Infinite 0.013 0.000 surface S5 Aspherical 33.966 2.330 1.544 55.865 4.043 47.278 surface S6 Aspherical −2.307 0.427 −0.254 surface S7 Aspherical 4.850 0.677 1.661 20.365 −7.614 −0.203 surface S8 Aspherical 2.344 0.669 −9.263 surface S9 Aspherical −5.405 2.361 1.498 82.571 3.332 −1.979 surface S10 Aspherical −1.457 0.349 −3.693 surface S11 Aspherical 10.411 1.861 1.544 55.865 −7.362 −5.099 (AAS) surface S12 Aspherical 2.719 0.690 −49.586 (AAS) surface S13 Spherical Infinite 0.210 1.517 64.167 0.000 surface S14 Spherical Infinite 0.338 0.000 surface

[0288] Based on the data in Table 25, the design parameters of the optical lens 45 in Implementation 7 of this application may be obtained, and are shown in Table 26.

TABLE-US-00026 TABLE 26 Design parameters of an optical lens 45 in Implementation 7 f1 (mm) 38.003 f4 (mm) −7.614 f2 (mm) −3.126 f5 (mm) 3.332 f3 (mm) 4.043 f6 (mm) −7.362 f(mm) 4.092 |f1/f| 9.287 |f2/f| 0.763 |f3/f| 0.988 |f4/f| 1.860 |f5/f| 0.814 |f6/f| 1.799 f2/f1 −0.082 f4/f3 −1.883 FOV (°) 113 f/EPD 2.05 T45/f 0.164 ImagH (mm) −3.190 TTL (mm) 12.2892 ImagH/TTL −0.260 (T23 + T56)/TTL 0.104 R6/R10 1.582 Fno 2.05

[0289] It may be learned from Table 26 that the field of view (FOV) of the optical lens 45 is 113° and the F-number (Fno) is 2.23. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In this implementation, TTL is 12.2892 mm, ImagH is −3.190 mm, and

[0290] ImagH/TTL=−0.260. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0291] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 7 of this application are shown in the following Table 27.

TABLE-US-00027 TABLE 27 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 7 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S1 4.5851E−05 −1.1944E−05 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S2 5.0823E−04 1.4852E−05 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S3 2.3829E−03 −5.9726E−05 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S4 7.6679E−03 −1.6866E−04 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S5 −1.3144E+00 2.7732E−01 −1.3261E−01 −3.6522E−03 3.3210E−02 −5.0816E−02 −3.2074E−02 S6 −3.5654E+00 −4.4067E−01 4.0940E−01 1.6636E−01 −1.5404E−01 −1.1443E−01 −3.2480E−02 S7 −1.7736E+00 3.8152E−01 −1.9297E−02 −2.4216E−03 −6.0501E−03 2.5367E−03 1.6128E−03 S8 −1.3978E+00 3.3036E−01 −1.3787E−01 −3.9654E−02 −2.3089E−02 −1.2913E−03 3.7844E−04 S9 2.0355E+00 −8.8988E−02 −1.5832E−01 2.3324E−01 −7.0980E−03 1.1812E−02 −1.6392E−02 S10 1.4289E+00 2.8523E+00 −1.1320E−01 −1.9060E−01 −2.9395E−01 −1.8131E−01 −7.2198E−02

[0292] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00015]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0293] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0294] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0295] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 7 of this application are shown in the following Table 28.

TABLE-US-00028 TABLE 28 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 7 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11 6.668E−03 1.175E−02 6.311E−03 −6.180E−04 −1.804E−03 −1.676E−03 −5.758E−04 1.069E−05 S12 −4.483E−03 −8.941E−03 −3.364E−03 2.009E−04 6.978E−04 4.358E−04 2.009E−04 −3.719E−06 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11 5.853E−05 7.592E−05 3.975E−05 1.891E−05 −2.511E−08 6.845E−07 1.918E−06 2.172E−06 S12 −2.829E−05 −3.398E−05 −2.620E−05 −3.295E−06 8.833E−08 4.089E−07 6.957E−07 1.611E−06 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11 5.062E−07 8.016E−08 −1.636E−08 −1.660E−08 −8.334E−08 −2.178E−07 −2.625E−07 5.546E−10 S12 −1.131E−06 1.002E−08 −4.116E−09 2.446E−08 −2.125E−08 2.865E−08 1.008E−07 −1.885E−07 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11 −1.661E−08 8.853E−10 1.714E−09 −1.488E−09 −1.370E−08 −9.986E−09 −5.636E−08 9.597E−10 S12 −1.175E−10 4.486E−11 1.526E−09 −1.464E−09 −2.204E−09 3.765E−09 −1.963E−09 −1.855E−08 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11 2.655E−10 1.914E−11 1.235E−10 1.708E−10 −6.540E−10 −8.277E−10 −4.475E−09 −9.490E−09 S12 3.343E−11 −4.311E−12 1.422E−10 −2.174E−10 −3.579E−10 −1.593E−10 −4.155E−11 4.528E−10 Surface sequence number A.sub.150 A.sub.152 S11 −7.283E−10 −1.660E−12 S12 8.721E−10 −3.908E−12

[0296] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients.

[0297] The foregoing parameters are substituted into the following formulas:

[00016]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0298] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0299] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0300] FIG. 23 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 22. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=4.8350%, and TV distortion in the imaging range of the optical lens 45 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0301] Implementation 8: FIG. 24 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has positive focal power.

[0302] In this implementation, an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 24 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0303] Design parameters of the optical lens 45 in Implementation 8 of this application are shown in the following Table 29.

TABLE-US-00029 TABLE 29 Design parameters of an optical lens 45 in Implementation 8 Material Surface Surface Curvature Refractive Abbe Focal Conic number type radius Thickness index number length coefficient OBJ Spherical Infinite Infinite 0.000 surface S1 Aspherical 22.386 0.350 1.544 55.865 450.799 22.203 surface S2 Aspherical 16.000 0.348 −22.149 surface S3 Aspherical −3.040 0.896 1.544 55.865 −14.904 −0.031 surface S4 Aspherical −5.355 0.246 0.043 surface STOP Spherical Infinite 0.000 0.000 surface S5 Aspherical 15.916 2.001 1.544 55.865 3.365 42.112 surface S6 Aspherical −1.988 0.836 −7.154 surface S7 Aspherical 120.000 0.707 1.661 20.365 −3.831 −93.658 surface S8 Aspherical 2.501 0.506 −13.187 surface S9 Aspherical −4.766 2.188 1.498 82.571 3.126 1.384 surface S10 Aspherical −1.462 0.102 −2.312 surface S11 Aspherical 7.116 1.970 1.544 55.865 90.409 −5.000 (AAS) surface S12 Aspherical 7.500 0.482 −15.993 (AAS) surface S13 Spherical Infinite 0.252 1.517 64.167 0.000 surface S14 Spherical Infinite 0.268 0.000 surface

[0304] Based on the data in Table 29, the design parameters of the optical lens 45 in Implementation 8 of this application may be obtained, and are shown in the following Table 30.

TABLE-US-00030 TABLE 30 Design parameters of an optical lens 45 in Implementation 8 f1 (mm) 450.799 f4 (mm) −3.831 f2 (mm) −14.904 f5 (mm) 3.126 f3 (mm) 3.365 f6 (mm) 90.409 f(mm) 3.234 |f1/f| 139.386 |f2/f| 4.608 |f3/f| 1.041 |f4/f| 1.185 |f5/f| 0.967 |f6/f| 27.954 f2/f1 −0.033 f4/f3 −1.138 FOV (°) 130 f/EPD 2.24 T45/f 0.156 ImagH (mm) 4.995 TTL (mm) 11.1277 ImagH/TTL 0.445 (T23 + T56)/TTL 0.031 R6/R10 1.359 Fno 2.24

[0305] It may be learned from Table 30 that the field of view (FOV) of the optical lens 45 is 130° and the F-number (Fno) is 2.23. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In this implementation, TTL is 11.1277 mm, ImagH is 4.995 mm, and

[0306] ImagH/TTL=0.445. In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0307] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 8 of this application are shown in the following Table 31.

TABLE-US-00031 TABLE 31 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 8 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S1 1.4762E−03 1.7478E−05 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S2 −7.2268E−03 −5.0910E−04 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S3 3.0997E+00 2.9531E−02 1.7439E−01 −3.8770E−02 −1.6703E−02 −1.6440E−02 −7.3926E−04 S4 4.9057E+01 9.6124E+00 −3.2636E+00 −2.5320E+0 −4.8540E−01 −1.5692E−02 1.9548E−02 S5 1.2486E−02 −3.2960E−02 8.6854E−03 2.8498E−03 1.5030E−03 −6.6726E−04 −3.4940E−04 S6 −5.9267E−01 2.7938E−02 −2.7908E−02 −6.2007E−03 −6.4321E−03 −1.9555E−03 −5.7225E−04 S7 −7.5223E−01 1.5932E−01 −8.9152E−03 9.3672E−04 −6.8548E−04 −4.4212E−04 1.4436E−03 S8 −6.0014E−01 1.6298E−01 −1.8353E−02 4.4839E−03 −1.9129E−03 −1.1461E−03 2.2716E−04 S9 3.7758E−01 1.2345E−01 −2.2225E−02 2.8058E−04 −1.5228E−04 2.2063E−04 −1.5353E−04 S10 −4.5841E−01 3.2003E−01 −2.1905E−03 −1.7138E−03 8.7588E−05 9.4878E−04 4.7193E−03

[0308] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00017]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0309] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the first lens 451, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained.

[0310] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0311] In addition, design parameters of anamorphic aspherical surface coefficients of the sixth lens 456 in Implementation 8 of this application are shown in the following Table 32.

TABLE-US-00032 TABLE 32 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 8 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S11 2.682E−02 3.993E−02 2.540E−02 −4.674E−03 −9.383E−03 −9.888E−03 −4.116E−03 4.235E−04 S12 −3.024E−02 −5.097E−02 −2.806E−02 7.551E−03 2.109E−02 2.199E−02 7.350E−03 −1.216E−03 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S11 0.000E+00 1.409E−03 2.397E−03 1.170E−03 4.005E−04 −3.713E−05 −2.216E−04 −4.414E−04 S12 0.000E+00 −4.917E−03 −7.495E−03 −4.840E−03 −1.223E−03 1.283E−04 6.486E−04 1.282E−03 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S11 −4.218E−04 −2.316E−04 −4.316E−05 3.168E−06 1.923E−05 5.004E−05 6.872E−05 4.909E−05 S12 1.286E−03 6.524E−04 1.279E−04 −7.854E−06 −4.721E−05 −1.180E−04 −1.584E−04 −1.153E−04 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S11 2.359E−05 3.129E−06 −1.355E−07 −8.047E−07 −2.100E−06 −4.761E−06 −3.869E−06 −2.884E−06 S12 −4.589E−05 −8.014E−06 2.568E−07 1.797E−06 5.426E−06 8.817E−06 9.076E−06 5.497E−06 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S11 5.609E−07 −1.162E−07 5.605E−10 1.221E−08 9.482E−09 8.463E−08 6.482E−08 7.536E−08 S12 1.551E−06 2.551E−07 −3.746E−09 −3.127E−08 −8.672E−08 −1.967E−07 −2.493E−07 −1.759E−07 Surface sequence number A.sub.150 A.sub.152 S11 3.248E−08 −1.236E−07 S12 −1.279E−07 −3.314E−08

[0312] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients. The foregoing parameters are substituted into the following formulas:

[00018]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0313] After the foregoing operation, surface types of the object side surface and the image side surface of the sixth lens 456 in this implementation can be obtained through design.

[0314] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0315] FIG. 25 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 24. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=3.4559%, and TV distortion in the imaging range of the optical lens 45 is small. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion. Therefore, the sixth lens 456 has “a plurality of functions”.

[0316] Implementation 9: FIG. 26 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has negative focal power.

[0317] In this implementation, both an object side surface 4511 and an image side surface 4512 of the first lens 451 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the second lens 452, the third lens 453, the fourth lens 454, the fifth lens 455, and the sixth lens 456 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces. FIG. 26 shows an optical axis direction of the optical lens 45 by using a solid line with an arrow. In addition, the direction of the arrow represents a direction from the object side to the image side.

[0318] Design parameters of the optical lens 45 in Implementation 9 of this application are shown in the following Table 33.

TABLE-US-00033 TABLE 33 Design parameters of an optical lens 45 in Implementation 9 Material Surface Surface Curvature Refractive Abbe Focal Conic number type radius Thickness index number length coefficient OBJ Spherical Infinite Infinite 0.000 surface S1 Aspherical 21.574 0.250 1.544 55.865 239.029 146.140 (AAS) surface S2 Aspherical 25.735 0.221 −100.000 (AAS) surface S3 Aspherical 53.729 0.499 1.901 37.054 −13.708 0.000 surface S4 Aspherical 10.047 0.285 0.000 surface STOP Spherical Infinite 0.079 0.000 surface S5 Aspherical 30.160 1.169 1.544 55.865 3.144 −129.407 surface S6 Aspherical −1.798 0.285 0.292 surface S7 Aspherical 4.524 0.497 1.661 20.365 −4.375 0.000 surface S8 Aspherical 1.698 0.522 −12.235 surface S9 Aspherical −2.360 1.514 1.498 82.571 2.051 −1.929 surface S10 Aspherical −0.932 0.099 −3.193 surface S11 Aspherical 10.054 1.277 1.544 55.865 −7.588 −79.632 surface S12 Aspherical 2.804 0.751 −69.210 surface S13 Spherical Infinite 0.210 1.517 64.167 0.000 surface S14 Spherical Infinite 0.390 0.000 surface

[0319] Based on the data in Table 33, the design parameters of the optical lens 45 in Implementation 9 of this application may be obtained, and are shown in the following Table 34.

TABLE-US-00034 TABLE 34 Design parameters of an optical lens 45 in Implementation 9 f1 (mm) 239.029 f4 (mm) −4.375 f2 (mm) −13.708 f5 (mm) 2.051 f3 (mm) 3.144 f6 (mm) −7.588 f(mm) 2.615 |f1/f| 91.421 |f2/f| 5.242 |f3/f| 1.203 |f4/f| 1.673 |f5/f| 0.784 |f6/f| 2.901 f2/f1 −0.057 f4/f3 −1.391 FOV (°) 125 f/EPD 2.23 T45/f 0.2 ImagH (mm) 4.89 TTL (mm) 8.0 ImagH/TTL 0.63 (T23 + T56)/TTL 0.048 R6/R10 1.928 Fno 2.23

[0320] It may be learned from Table 34 that the field of view (FOV) of the optical lens 45 is 125° and the F-number (Fno) is 2.23. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In this implementation, TTL is 8.0 mm, ImagH is 4.89 mm, and ImagH/TTL=0.63.

[0321] In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0322] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the second lens 452, the third lens 453, the fourth lens 454, the fifth lens 455, and the sixth lens 456) in Implementation 9 of this application are shown in the following Table 35.

TABLE-US-00035 TABLE 35 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 9 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S3 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S4 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 S5 −1.6177E+00 1.0453E+00 2.6887E−01 3.5938E−02 6.3268E−02 −2.1583E−02 −2.2346E−02 S6 −2.8137E+00 −1.6619E−01 2.1352E−01 7.9381E−02 −9.4571E−02 −5.4848E−02 −1.3948E−02 S7 −1.1177E+00 2.7400E−01 −3.6477E−02 −2.7589E−03 −2.5818E−03 −1.3641E−03 1.7403E−05 S8 −9.6010E−01 2.2340E−01 −8.7433E−02 −1.8932E−02 −2.1134E−02 −5.1406E−03 −1.7481E−03 S9 2.8866E−01 −1.3119E−01 −1.0555E−01 2.5540E−01 −6.2301E−02 −1.0146E−01 −4.9388E−02 S10 8.9235E−01 2.0611E+00 −1.8778E−01 −1.5534E−01 −2.0511E−01 −1.7145E−01 −7.3918E−02 S11 1.3487E−02 −5.7844E−04 9.6591E−06 −2.5138E−08 −1.3582E−09 2.3184E−11 −2.5945E−13 S12 −2.9340E−02 5.0352E−04 −4.5837E−06 −3.0960E−10 6.1511E−10 5.4947E−12 −2.2045E−13

[0323] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00019]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0324] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the second lens 452, the third lens 453, the fourth lens 454, the fifth lens 455, and the sixth lens 456 can be obtained through design.

[0325] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0326] In addition, design parameters of anamorphic aspherical surface coefficients of the first lens 451 in Implementation 9 of this application are shown in the following Table 36.

TABLE-US-00036 TABLE 36 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 9 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 S1 1.639E−02 4.155E−02 1.904E−02 −2.331E−03 8.124E−03 2.045E−02 7.081E−03 7.159E−03 S2 3.662E−03 3.053E−02 1.182E−02 1.952E−02 4.634E−02 6.675E−02 1.869E−02 3.643E−03 Surface sequence number A.sub.38 A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 S1 7.968E−03 2.355E−02 −2.004E−03 −8.995E−03 4.926E−04 1.077E−02 −6.689E−04 6.517E−03 S2 1.759E−02 2.558E−02 3.977E−03 −5.645E−05 1.481E−03 4.425E−03 3.646E−02 −2.376E−03 Surface sequence number A.sub.63 A.sub.65 A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 S1 1.333E−02 1.619E−02 −1.777E−04 −6.860E−03 5.177E−03 1.091E−02 −2.038E−02 6.196E−03 S2 1.836E−02 −9.104E−04 1.702E−03 −4.239E−03 −5.167E−03 −1.852E−02 8.694E−03 8.496E−03 Surface sequence number A.sub.90 A.sub.105 A.sub.107 A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 S1 −1.409E−02 −6.783E−05 −4.739E−04 4.578E−04 4.629E−03 4.982E−03 5.177E−03 1.091E−02 S2 −1.470E−03 −1.837E−06 −1.648E−03 −8.654E−03 1.636E−02 −3.205E−02 −5.167E−03 −1.852E−02 Surface sequence number A.sub.119 A.sub.136 A.sub.138 A.sub.140 A.sub.142 A.sub.144 A.sub.146 A.sub.148 S1 −2.038E−02 6.196E−03 −1.409E−02 −6.783E−05 −4.739E−04 4.578E−04 4.629E−03 4.982E−03 S2 8.694E−03 8.496E−03 −1.470E−03 −1.837E−06 −1.648E−03 −8.654E−03 1.636E−02 −3.205E−02 Surface sequence number A.sub.150 A.sub.152 S1 −2.070E−03 −8.568E−04 S2 −8.405E−03 2.722E−04

[0327] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients.

[0328] The foregoing parameters are substituted into the following formulas:

[00020]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0329] After the foregoing operation, surface types of the object side surface and the image side surface of the first lens 451 in this implementation can be obtained through design.

[0330] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0331] FIG. 27 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 26. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. Specifically, in this implementation, a maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=1.4771%, and TV distortion in the imaging range of the optical lens 45 is small. It may be understood that the object side surface 4511 and the image side surface 4512 of the first lens 451 are set as anamorphic aspherical surfaces. Therefore, when light reflected by a to-be-imaged scene is incident from a lens close to the object side, obvious distortion caused by a large field of view can be corrected, and a correction effect can be achieved more easily.

[0332] Implementation 10: FIG. 28 is a schematic structural diagram of still another implementation of lenses of the optical lens shown in FIG. 5. In this implementation, the optical lens 45 includes six lenses. The optical lens 45 includes a first lens 451, a second lens 452, a third lens 453, a fourth lens 454, a fifth lens 455, and a sixth lens 456 that are sequentially arranged from an object side to an image side. The first lens 451, the third lens 453, and the fifth lens 455 all have positive focal power. The second lens 452 and the fourth lens 454 both have negative focal power. The sixth lens 456 has negative focal power.

[0333] In this implementation, both an object side surface 4511 and an image side surface 4512 of the first lens 451 are anamorphic aspherical surfaces. Both an object side surface 4561 and an image side surface 4562 of the sixth lens 456 are anamorphic aspherical surfaces. Other lenses are all non-anamorphic lenses (namely, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 are all non-anamorphic lenses), and both an object side surface and an image side surface of the non-anamorphic lens are non-anamorphic aspherical surfaces.

[0334] Design parameters of the optical lens 45 in Implementation 10 of this application are shown in the following Table 37.

TABLE-US-00037 TABLE 37 Design parameters of an optical lens 45 in Implementation 10 Material Surface Surface Curvature Refractive Abbe Focal Conic number type radius Thickness index number length coefficient OBJ Spherical Infinite Infinite 0.000 surface S1 Aspherical 21.69 0.25 1.544 55.865 307.23 146.14 (AAS) surface S2 Aspherical 24.81 0.22 −100.00 (AAS) surface S3 Aspherical 55.29 0.49 1.901 37.054 −13.50 −4.09 surface S4 Aspherical 9.98 0.30 −0.21 surface STOP Spherical Infinite 0.08 0.00 surface S5 Aspherical 29.99 1.18 1.544 55.865 3.14 −220.49 surface S6 Aspherical −1.79 0.28 0.29 surface S7 Aspherical 4.50 0.50 1.661 20.365 −4.44 −0.08 surface S8 Aspherical 1.71 0.52 −12.49 surface S9 Aspherical −2.36 1.51 1.544 55.865 2.04 −1.93 surface S10 Aspherical −0.93 0.10 −3.18 surface S11 Aspherical 9.03 1.29 1.544 55.865 −7.96 −83.14 (AAS) surface S12 Aspherical 2.79 0.73 −77.21 (AAS) surface S13 Spherical Infinite 0.21 1.517 64.167 0.000 surface S14 Spherical Infinite 0.37 0.000 surface

[0335] Based on the data in Table 38, the design parameters of the optical lens 45 in Implementation 10 of this application may be obtained, and are shown in the following Table 38.

TABLE-US-00038 TABLE 38 Design parameters of an optical lens 45 in Implementation 10 f1 (mm) 307.23 f4 (mm) −4.44 f2 (mm) 13.5 f5 (mm) 2.04 f3 (mm) 3.14 f6 (mm) −7.96 f(mm) 2.54 |f1/f| 120.967 |f2/f| 5.314 |f3/f| 1.236 |f4/f| 1.748 |f5/f| 0.804 |f6/f| 3.134 f2/f1 −0.044 f4/f3 −1.414 FOV (°) 135 f/EPD 2.3 T45/f 0.199 ImagH (mm) 4.36 TTL (mm) 8.1 ImagH/TTL 0.538 (T23 + T56)/TTL 0.059 R6/R10 1.929 Fno 2.3

[0336] It may be learned from Table 38 that the field of view (FOV) of the optical lens 45 is 135° and the F-number (Fno) is 2.3. In other words, the optical lens 45 in this application can implement a large field of view and a wide aperture, and can better meet a photographing requirement. In this implementation, TTL is 8.1 mm, ImagH is 4.36 mm, and ImagH/TTL=0.538.

[0337] In other words, when the effective pixel region formed on the photosensitive chip 42 through projection by the optical lens 45 in this implementation is large, the total optical length of the optical lens 45 can be small. Therefore, when high imaging quality is obtained, the length of the optical lens 45 can be small, and the optical lens 45 can be applied to a thin electronic device such as a mobile phone or a tablet.

[0338] Design parameters of aspherical surface coefficients of the non-anamorphic lenses (namely, the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455) in Implementation 10 of this application are shown in the following Table 39.

TABLE-US-00039 TABLE 39 Design parameters of non-anamorphic lenses of an optical lens 45 in Implementation 10 Surface number A.sub.0 A.sub.1 A.sub.2 A.sub.3 A.sub.4 A.sub.5 A.sub.6 S3 −1.00E−04 7.83E−04 −6.92E−05 3.80E−05 1.04E−06 4.63E−06 −3.31E−05 S4 −1.78E−06 −2.68E−04 7.41E−04 −1.10E−04 −2.31E−06 −3.78E−05 1.35E−05 S5 −1.64E+00 1.05E+00 2.67E−01 3.65E−02 6.31E−02 −2.17E−02 −2.20E−02 S6 −2.82E+00 −1.60E−01 2.09E−01 8.10E−02 −9.52E−02 −5.50E−02 −1.33E−02 S7 −1.12E+00 2.74E−01 −3.60E−02 −2.73E−03 −2.53E−03 −1.49E−03 5.66E−05 S8 −9.60E−01 2.23E−01 −8.79E−02 −1.84E−02 −2.14E−02 −5.30E−03 −1.59E−03 S9 2.90E−01 −1.32E−01 −1.04E−01 2.55E−01 −6.16E−02 −1.03E−01 −4.89E−02 S10 8.90E−01 2.06E+00 −1.90E−01 −1.55E−01 −2.05E−01 −1.73E−01 −7.09E−02

[0339] Symbols such as A.sub.0, A.sub.1, A.sub.2, A.sub.3, A.sub.4, A.sub.5, and A.sub.6 represent the aspherical surface coefficients. The foregoing parameters are substituted into the following formula:

[00021]$z=\frac{c{r}^2}{1+\sqrt{1-K{c}^2{r}^2}}+u^4\underset{m=0}{\overset{M}{.Math.}}{A}_m{Q}_m^{con}\left(u^2\right)$

[0340] After the foregoing operation, surface types of the object side surfaces and the image side surfaces of the second lens 452, the third lens 453, the fourth lens 454, and the fifth lens 455 can be obtained through design.

[0341] In this implementation, z is a vector height of the aspherical surface, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, K is a conic constant, A.sub.m is the aspherical surface coefficient, r.sub.max is a maximum value of the radial coordinate, and u=r/r.sub.max.

[0342] In addition, design parameters of anamorphic aspherical surface coefficients of the first lens 451 and the sixth lens 456 in Implementation 10 of this application are shown in the following Table 40.

TABLE-US-00040 TABLE 40 Design parameters of anamorphic aspherical surfaces of an optical lens 45 in Implementation 10 Surface sequence number A.sub.10 A.sub.12 A.sub.14 A.sub.21 A.sub.23 A.sub.25 A.sub.27 A.sub.36 A.sub.38 S1 1.57E−02 4.11E−02 1.82E−02 −2.18E−03 8.58E−03 2.12E−02 7.25E−03 7.17E−03 8.52E−03 S2 4.91E−03 3.35E−02 1.32E−02 1.94E−02 4.62E−02 6.63E−02 1.86E−02 3.56E−03 1.72E−02 S11 −2.12E+03 3.31E−02 1.65E−02 −2.44E+06 −1.77E+08 −1.95E+08 −2.90E+07 −3.75E+08 −4.76E+10 S12 −3.14E−02 −6.38E−02 −3.20E−02 3.24E−03 9.61E−03 9.70E−03 3.23E−03 −1.26E−04 −5.14E−04 Surface sequence number A.sub.40 A.sub.42 A.sub.44 A.sub.55 A.sub.57 A.sub.59 A.sub.61 A.sub.63 A.sub.65 S1 2.43E−02 −1.28E−03 −8.79E−03 5.32E−04 1.09E−02 −3.88E−04 6.84E−03 1.37E−02 1.62E−02 S2 2.49E−02 3.28E−03 −1.84E−04 1.44E−03 4.21E−03 3.60E−02 −2.88E−03 1.82E−02 −9.88E−04 S11 −2.43E+10 −7.16E+10 −1.05E+10 −2.83E+12 −4.50E+12 2.39E+13 1.48E+13 9.29E+12 −2.97E+11 S12 −7.76E−04 −5.03E−04 −1.26E−04 −7.08E−07 −3.73E−06 −8.48E−06 −7.35E−06 −3.15E−06 −6.32E−07 Surface sequence number A.sub.78 A.sub.80 A.sub.82 A.sub.84 A.sub.86 A.sub.88 A.sub.90 A.sub.105 A.sub.107 S1 −1.66E−04 −6.81E−03 5.18E−03 1.07E−02 −2.04E−02 6.41E−03 −1.41E−02 −6.40E−05 −4.86E−04 S2 1.69E−03 −4.19E−03 −5.36E−03 −1.87E−02 8.55E−03 8.49E−03 −1.41E−03 5.64E−06 −1.46E−03 S11 2.83E+14 2.26E+15 5.20E+16 −1.77E+16 9.17E+16 6.89E+16 5.33E+15 1.65E+18 4.68E+18 S12 2.65E−07 1.61E−06 3.98E−06 5.41E−06 3.98E−06 1.65E−06 2.71E−07 1.79E−08 1.29E−07 Surface sequence number A.sub.109 A.sub.111 A.sub.113 A.sub.115 A.sub.117 A.sub.119 A.sub.136 A.sub.138 A.sub.140 S1 3.85E−04 4.29E−03 4.55E−03 −8.79E−03 −2.35E−03 5.86E−03 1.15E−05 1.37E−03 −1.70E−03 S2 −8.40E−03 1.61E−02 −3.20E−02 −2.12E−05 −5.10E−03 1.25E−03 −6.05E−04 2.27E−03 4.10E−03 S11 1.41E+19 −1.77E+19 −7.12E+19 2.47E+20 1.17E+20 6.80E+18 2.26E+21 8.95E+21 −2.58E+22 S12 3.88E−07 6.53E−07 6.54E−07 3.77E−07 1.35E−07 1.81E−08 −1.75E−09 −1.36E−08 −4.74E−08 Surface sequence number A.sub.142 A.sub.144 A.sub.146 A.sub.148 A.sub.150 A.sub.152 S1 −9.27E−03 −1.02E−02 1.77E−02 2.24E−03 −2.04E−03 −8.66E−04 S2 −8.35E−02 7.71E−02 7.91E−03 −1.37E−02 −7.51E−03 2.74E−04 S11 −7.49E+22 −1.18E+23 −1.48E+23 5.94E+23 9.67E+22 6.28E+21 S12 −9.40E−08 −1.18E−07 −9.33E−08 −5.04E−08 −1.22E−08 −1.75E−09

[0343] Symbols such as A.sub.10, A.sub.12, A.sub.14, A.sub.21, A.sub.23, A.sub.25, and A.sub.27 represent polynomial coefficients.

[0344] The foregoing parameters are substituted into the following formulas:

[00022]$z=\frac{c{r}^2}{1+\sqrt{1-\left(1+k\right)c^2{r}^2}}+\underset{i=1}{\overset{N}{.Math.}}{A}_i{E}_i\left(x,y\right)\underset{i=1}{\overset{N}{.Math.}}{A}_i{x}^m{y}^n=A_1{x}^1{y}^0+A_2{x}^0{y}^1+A_3{x}^2{y}^0+A_4{x}^1{y}^1+A_5{x}^0{y}^2+A_6{x}^3{y}^0+A_7{x}^2{y}^1+A_8{x}^1{y}^2+A_9{x}^0{y}^3+A_{10}{x}^4{y}^0+.Math.+A_{152}{x}^0{y}^{16}$

[0345] After the foregoing operation, the object side surface 4511 and the image side surface 4512 of the first lens 451 and the object side surface 4561 and the image side surface 4562 of the sixth lens 456 in this implementation can be obtained through design.

[0346] In this implementation, z is a vector height parallel to a Z-axis, N is a total quantity of polynomial coefficients in series, A is a coefficient of an i.sup.th extended polynomial, r is a radial coordinate of the aspherical surface, c is a spherical curvature of a vertex on the aspherical surface, and K is a conic constant. Polynomial coefficients (such as A.sub.1 and A.sub.2) that do not exist in the table are 0.

[0347] FIG. 29 is an imaging simulation diagram of each lens of the optical lens shown in FIG. 28. A solid-line grid is an ideal imaging grid diagram, and a grid structure formed by a symbol “X” is a schematic diagram of imaging by the optical lens 45 in this implementation. It may be learned from the figure that imaging by the optical lens 45 in this implementation is basically the same as ideal imaging, and TV distortion in an imaging range of the optical lens 45 is small. A maximum value TDT of TV distortion in the imaging range of the optical lens 45 meets |TDT|=1.8%, and TV distortion in the imaging range of the optical lens 45 is small. It may be understood that the object side surface 4511 and the image side surface 4512 of the first lens 451 are set as anamorphic aspherical surfaces. Therefore, when light reflected by a to-be-imaged scene is incident from a lens close to the object side, obvious distortion caused by a large field of view can be corrected, and a correction effect can be achieved more easily. In addition, when the object side surface 4561 and the image side surface 4562 of the sixth lens 456 are set as anamorphic aspherical surfaces, the sixth lens 456 can correct field curvature and astigmatism in imaging by the optical lens 45, and can also correct distortion.

[0348] In the foregoing implementations, the first lens 451, the third lens 453, and the fifth lens 455 have positive focal power through setting, the second lens 452 and the fourth lens 454 have negative focal power through setting, and the sixth lens 456 has positive focal power or negative focal power through setting. Therefore, when it is ensured that the optical lens 45 implements good imaging quality, the field of view of the optical lens 45 can be increased to a large degree to implement ultra-wide-angle setting of the optical lens 45.

[0349] In addition, as the field of view of the optical lens is increased, imaging distortion of the optical lens becomes more obvious. For example, when the field of view of the optical lens reaches 100°, imaging distortion of the optical lens has been greater than 10%. For ultra-wide-angle setting of the optical lens, imaging distortion of the optical lens is more obvious, and imaging quality is poorer. In this application, at least one anamorphic aspherical surface is disposed in the lenses of the optical lens 45 that implements an ultra-wide-angle design. Therefore, a design degree of freedom of an optical system is improved. In addition, imaging quality of the optical lens can be optimized and distortion of the optical lens can be corrected by using asymmetry of a free region, so that good imaging quality of the optical lens is ensured.

[0350] Therefore, the optical lens 45 in this implementation can implement ultra-wide-angle photographing, and can also resolve a distortion problem in ultra-wide-angle imaging to a large degree. In other words, in this implementation, the ultra-wide-angle optical lens 45 with small imaging distortion is designed.

[0351] The foregoing descriptions are merely specific implementations of this application, but are not intended to limit the protection scope of this application. Any variation or replacement readily figured out by a person skilled in the art within the technical scope disclosed in this application shall fall within the protection scope of this application. Therefore, the protection scope of this application shall be subject to the protection scope of the claims.