CAMERA LENS, CAMERA MODULE, AND ELECTRONIC DEVICE

Abstract

A camera lens including a first lens, a prism, and a plurality of lenses. The first lens has positive focal power, and an object-side surface of the first lens is a convex surface. An object-side surface of the prism is in contact with an image-side surface of the first lens. The prism refracts, from a first optical axis to a second optical axis intersecting the first optical axis, light received from the first lens. The plurality of lenses include at least three lenses, and the plurality of lenses are sequentially disposed along the second optical axis.

Claims

1. A camera lens, comprising: a first lens along a direction from an object field to an image field, the first lens having positive focal power, wherein an object-side surface of the first lens is a convex surface; a prism along the direction from the object field to the image field, wherein an object-side surface of the prism is in contact with an image-side surface of the first lens, and the prism is configured to refract, from a first optical axis to a second optical axis intersecting the first optical axis, light received from the first lens; and a plurality of lenses along the direction from the object field to the image field, wherein the plurality of lenses comprise at least three lenses, the plurality of lenses are sequentially disposed along the second optical axis, an object-side surface and an image-side surface of a lens of the plurality of lenses that is closest to the prism are aspheric surfaces, and an image-side surface of a lens of the plurality of lenses that is closest to the image field of the camera lens is a convex surface.

2. The camera lens according to claim 1, wherein the plurality of lenses comprises: a second lens having negative focal power; a third lens having positive focal power; and a fourth lens having focal power, wherein the second lens, the third lens, and the fourth lens are sequentially disposed along the second optical axis.

3. The camera lens according to claim 2, wherein a ratio of a focal length f2 of the second lens to a total focal length of the camera lens is: $0.1.Math.\frac{f2}{f}.Math.0.9.$

4. The camera lens according to claim 1, wherein the plurality of lenses comprises: a second lens having focal power; a third lens having focal power; a fourth lens having focal power; and a fifth lens having focal power, wherein the second lens, the third lens, the fourth lens, and the fifth lens are sequentially disposed along the second optical axis.

5. The camera lens according to claim 4, wherein a ratio of a focal length f2 of the second lens to a total focal length f of the camera lens is: $0\text{.2}.Math.\frac{f2}{f}.Math.1.3.$

6. The camera lens according to claim 1, wherein the plurality of lenses comprises: a second lens having positive focal power; a third lens having negative focal power; a fourth lens having negative focal power; a fifth lens having positive focal power; and a sixth lens having negative focal power, wherein the second lens, the third lens, the fourth lens, the fifth lens, and the sixth lens are sequentially disposed along the second optical axis.

7. The camera lens according to claim 6, wherein a ratio of a focal length f2 of the second lens to a total focal length f of the camera lens is: $0\text{.2}.Math.\frac{f2}{f}.Math.18.$

8. The camera lens according to claim 1, wherein at least one of the plurality of lenses is a diffractive optical element.

9. The camera lens according to claim 1, wherein at least one of the plurality of lenses is a first zoom liquid lens.

10. The camera lens according to claim 1, wherein the camera lens further comprises: a second zoom liquid lens, wherein the second zoom liquid lens is disposed on a side of the first lens that faces the object field.

11. The camera lens according to claim 1, wherein the total focal length f of the camera lens is as follows: 14 mmf33 mm.

12. The camera lens according to claim 1, wherein a ratio of a curvature radius R of the lens of the plurality of lenses that is closest to the image field of the camera lens to the total focal length f of the camera lens is: $0\text{.2}.Math.\frac{R}{f}.Math.3.$

13. The camera lens according to claim 1, wherein a ratio of an Abbe number V1 of the first lens to an Abbe number V2 of the prism is: $.Math.\frac{V1}{V2}.Math.3.$

14. The camera lens according to claim 1, wherein the prism is made of a glass material, the first lens is made of a plastic material, and the first lens is bonded to the prism through a bonding layer.

15. The camera lens according to claim 1, wherein both the prism and the first lens are made of a plastic material, and the prism and the first lens form an integrated structure.

16. A camera module, comprising: a camera lens and an image sensor, wherein a photosensitive surface of the image sensor is opposite to an imaging plane of the camera lens, wherein the camera lens comprises: a first lens, having positive focal power, wherein an object-side surface of the first lens is a convex surface; a prism, wherein an object-side surface of the prism is in contact with an image-side surface of the first lens, and the prism is configured to refract, from a first optical axis to a second optical axis intersecting the first optical axis, light received from the first lens; and a plurality of lenses, wherein the plurality of lenses comprises at least three lenses, the plurality of lenses are sequentially disposed along the second optical axis, both an object-side surface and an image-side surface of a lens of the plurality of lenses that is closest to the prism are aspheric surfaces, and an image-side surface of a lens of the plurality of lenses that is closest to the image field of the camera lens is a convex surface.

17. The camera module according to claim 16, wherein the plurality of lenses comprise: a second lens having negative focal power; a third lens having positive focal power; and a fourth lens having focal power, wherein the second lens, the third lens, and the fourth lens are sequentially disposed along the second optical axis.

18. An electronic device, comprising: a processor; and a camera module, wherein the processor is connected to an image sensor in the camera module, and wherein the camera module comprises: a camera lens and an image sensor, wherein a photosensitive surface of the image sensor is opposite to an imaging plane of the camera lens, wherein the camera lens comprises: a first lens, having positive focal power, wherein an object-side surface of the first lens is a convex surface; a prism, wherein an object-side surface of the prism is in contact with an image-side surface of the first lens, and the prism is configured to refract, from a first optical axis to a second optical axis intersecting the first optical axis, light received from the first lens; and a plurality of lenses, wherein the plurality of lenses comprises at least three lenses, the plurality of lenses are sequentially disposed along the second optical axis, both an object-side surface and an image-side surface of a lens of the plurality of lenses that is closest to the prism are aspheric surfaces, and an image-side surface of a lens of the plurality of lenses that is closest to the image field of the camera lens is a convex surface.

19. The electronic device according to claim 18, wherein the plurality of lenses comprises: a second lens having negative focal power; a third lens having positive focal power; and a fourth lens having focal power, wherein the second lens, the third lens, and the fourth lens are sequentially disposed along the second optical axis.

20. The electronic device according to claim 18, wherein the plurality of lenses comprises: a second lens having positive focal power; a third lens having negative focal power; a fourth lens having negative focal power; a fifth lens having positive focal power; and a sixth lens having negative focal power, wherein the second lens, the third lens, the fourth lens, the fifth lens, and the sixth lens are sequentially disposed along the second optical axis.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] FIG. 1 is a schematic diagram of a structure of a camera lens in the conventional technology;

[0034] FIG. 2 is a schematic diagram of a partial structure of a camera lens;

[0035] FIG. 3a is a schematic diagram of a structure of an electronic device according to an embodiment of this application;

[0036] FIG. 3b is an exploded view of FIG. 3a;

[0037] FIG. 4 is a schematic diagram of a structure of a camera module according to an embodiment of this application;

[0038] FIG. 5 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0039] FIG. 6 is a diagram of an optical imaging path of a camera lens shown in FIG. 5;

[0040] FIG. 7 is a schematic diagram of a zoom principle of a zoom liquid lens according to an embodiment of this application;

[0041] FIG. 8a is a line graph of axial aberration of a camera lens shown in FIG. 5;

[0042] FIG. 8b is a line graph of lateral aberration of a camera lens shown in FIG. 5;

[0043] FIG. 8c is a line graph of distortion aberration of a camera lens shown in FIG. 5;

[0044] FIG. 8d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 5;

[0045] FIG. 9 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0046] FIG. 10a is a line graph of axial aberration of a camera lens shown in FIG. 9;

[0047] FIG. 10b is a line graph of lateral aberration of a camera lens shown in FIG. 9;

[0048] FIG. 1c is a line graph of distortion aberration of a camera lens shown in FIG. 9;

[0049] FIG. 10d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 9;

[0050] FIG. 11 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0051] FIG. 12a is a line graph of axial aberration of a camera lens shown in FIG. 11;

[0052] FIG. 12b is a line graph of lateral aberration of a camera lens shown in FIG. 11;

[0053] FIG. 12c is a line graph of distortion aberration of a camera lens shown in FIG. 11;

[0054] FIG. 12d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 11;

[0055] FIG. 13 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0056] FIG. 14a is a line graph of axial aberration of a camera lens shown in FIG. 13;

[0057] FIG. 14b is a line graph of lateral aberration of a camera lens shown in FIG. 13;

[0058] FIG. 14c is a line graph of distortion aberration of a camera lens shown in FIG. 13;

[0059] FIG. 14d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 13;

[0060] FIG. 15 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0061] FIG. 16a is a line graph of axial aberration of a camera lens shown in FIG. 15;

[0062] FIG. 16b is a line graph of lateral aberration of a camera lens shown in FIG. 15;

[0063] FIG. 16c is a line graph of distortion aberration of a camera lens shown in FIG. 15;

[0064] FIG. 16d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 15;

[0065] FIG. 17 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0066] FIG. 18a is a line graph of axial aberration of a camera lens shown in FIG. 17;

[0067] FIG. 18b is a line graph of lateral aberration of a camera lens shown in FIG. 17;

[0068] FIG. 19 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0069] FIG. 20a is a line graph of axial aberration of a camera lens shown in FIG. 19;

[0070] FIG. 20b is a line graph of lateral aberration of a camera lens shown in FIG. 19;

[0071] FIG. 20c is a line graph of distortion aberration of a camera lens shown in FIG. 19;

[0072] FIG. 20d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 19;

[0073] FIG. 21 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0074] FIG. 22a is a line graph of axial aberration of a camera lens shown in FIG. 21;

[0075] FIG. 22b is a line graph of lateral aberration of a camera lens shown in FIG. 21;

[0076] FIG. 22c is a line graph of distortion aberration of a camera lens shown in FIG. 21;

[0077] FIG. 22d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 21;

[0078] FIG. 23 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0079] FIG. 24a is a line graph of axial aberration of a camera lens shown in FIG. 23;

[0080] FIG. 24b is a line graph of lateral aberration of a camera lens shown in FIG. 23;

[0081] FIG. 24c is a line graph of distortion aberration of a camera lens shown in FIG. 23;

[0082] FIG. 24d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 23;

[0083] FIG. 25 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0084] FIG. 26a is a line graph of axial aberration of a camera lens shown in FIG. 25;

[0085] FIG. 26b is a line graph of lateral aberration of a camera lens shown in FIG. 25;

[0086] FIG. 26c is a line graph of distortion aberration of a camera lens shown in FIG. 25;

[0087] FIG. 26d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 25;

[0088] FIG. 27 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0089] FIG. 28a is a line graph of axial aberration of a camera lens shown in FIG. 27;

[0090] FIG. 28b is a line graph of lateral aberration of a camera lens shown in FIG. 27;

[0091] FIG. 28c is a line graph of distortion aberration of a camera lens shown in FIG. 27;

[0092] FIG. 28d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 27;

[0093] FIG. 29 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0094] FIG. 30a is a line graph of axial aberration of a camera lens shown in FIG. 29;

[0095] FIG. 30b is a line graph of lateral aberration of a camera lens shown in FIG. 29;

[0096] FIG. 30c is a line graph of distortion aberration of a camera lens shown in FIG. 29;

[0097] FIG. 30d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 29;

[0098] FIG. 31 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0099] FIG. 32a is a line graph of axial aberration of a camera lens shown in FIG. 31;

[0100] FIG. 32b is a line graph of lateral aberration of a camera lens shown in FIG. 31;

[0101] FIG. 32c is a line graph of distortion aberration of a camera lens shown in FIG. 31;

[0102] FIG. 32d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 31;

[0103] FIG. 33 is a schematic diagram of a structure of a camera lens according to an embodiment of this application;

[0104] FIG. 34a is a line graph of axial aberration of a camera lens shown in FIG. 33;

[0105] FIG. 34b is a line graph of lateral aberration of a camera lens shown in FIG. 33;

[0106] FIG. 34c is a line graph of distortion aberration of a camera lens shown in FIG. 33; and

[0107] FIG. 34d is a line graph of ideal distortion aberration of a camera lens shown in FIG. 33.

REFERENCE NUMERALS

[0108] 10: housing; 11: bezel; 12: rear cover; 20: camera decorative cover; 21: transparent window; 30: camera module; 301: camera lens; 302: image sensor; 40: mainboard; and 50: assembly opening; and [0109] 1: drive cavity; 2: optical cavity; 3: light exit surface; 4: permanent magnet; and 5: coil.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

[0110] For ease of understanding technical solutions, the following explains technical terms in this application with reference to FIG. 2.

[0111] Image-side surface and object-side surface: The image-side surface and the object-side surface are ranges in which an imaging ray passes. The imaging ray includes a chief ray and a marginal ray. The image-side surface is a surface facing an image field, and the object-side surface is a surface facing an object field.

[0112] Focal power: The focal power is equal to a difference between an image-side beam convergence degree and an object-side beam convergence degree, and represents a capability of an optical system to deflect incident parallel beams. The focal power is usually denoted as . A larger value of indicates stronger refraction for parallel beams. When is greater than 0, deflection is convergent. When is less than 0, deflection is divergent. When is equal to 0, planar refraction occurs. To be specific, axially parallel beams are still axially parallel beams after being refracted, without deflection.

[0113] Image height: A height of an image formed by a camera lens on an imaging plane is referred to as an image height, which is usually denoted as an IMH.

[0114] Thickness of a lens: A thickness of a lens on an optical axis is a thickness of the lens. As shown in FIG. 2, a thickness of a 1st lens is Ti.

[0115] Total track length (TTL): A length, on an optical axis, from an object-side surface of a 1.sup.st optical element facing an object side in a camera lens to an imaging plane is a total track length. As shown in FIG. 2, a length S, on an optical axis, from an object-side surface of the 1.sup.st lens to an imaging plane M is a TTL.

[0116] Aperture stop: The aperture stop is an apparatus for controlling an amount of light that enters a photosensitive surface of a camera through a camera lens. A size of the aperture stop is usually represented in an F/value form, for example, F/1.0.

[0117] The following describes in detail technical solutions in embodiments of this application with reference to accompanying drawings.

[0118] An embodiment of this application provides an electronic device. The electronic device includes a camera module having image shooting and video recording functions. The electronic device may include a mobile phone, a tablet computer (pad), an intelligent wearable product (for example, a smartwatch or a smart band), a monitor, an event data recorder, or the like. A specific form of the electronic device is not particularly limited in this embodiment of this application.

[0119] FIG. 3a is a three-dimensional diagram of an electronic device according to some embodiments of this application. FIG. 3b is an exploded view of the electronic device shown in FIG. 3a. In this embodiment, for example, the electronic device is a mobile phone. The electronic device includes a housing 10, a camera decorative cover 20, a camera module 30, and a mainboard 40.

[0120] The housing 10 is a housing structure formed by splicing a front cover (not shown in the figure), a bezel 11, and a rear cover 12, and is configured to protect internal electronic components and circuits of the electronic device.

[0121] An assembly opening 50 is provided on the rear cover 12. The camera decorative cover 20 covers the assembly opening 50, and the camera decorative cover 20 is configured to protect a rear-facing camera module of the electronic device. In some embodiments, the camera decorative cover 20 protrudes out of the housing 10. In this way, the camera decorative cover 20 can increase assembly space for the rear-facing camera module in the electronic device along a thickness direction of the electronic device. In some other implementations, the camera decorative cover 20 may alternatively not protrude out of the housing 10.

[0122] At least one transparent window 21 is provided on the camera decorative cover 20. The at least one transparent window 21 is configured to allow object light to enter the rear-facing camera module.

[0123] The camera module 30 is disposed in the housing 10, and the camera module 30 is configured to take a photo or record a video. There may be one or more camera modules 30 in the electronic device. When there is one camera module 30, the camera module 30 may serve as a front-facing camera module, or may serve as a rear-facing primary camera module or a rear-facing secondary camera module. The rear-facing secondary camera module includes but is not limited to a wide-angle camera module, a long-focus camera module, and the like. This is not specifically limited herein. When there are a plurality of camera modules 30, the plurality of camera modules 30 may respectively serve as a plurality of camera modules of a front-facing camera module, a rear-facing primary camera module, and a rear-facing secondary camera module. FIG. 3a and FIG. 3b show only an example in which there is one camera module 30 and the camera module 30 serves as a rear-facing primary camera module. This shall not be construed as a special limitation on this application.

[0124] With reference to FIG. 4, the camera module 30 includes a camera lens 301 and an image sensor 302. A photosensitive surface of the image sensor 302 is opposite to an imaging plane of the camera lens 301. A processing unit connected to the image sensor 302 is integrated into the mainboard. An optical image generated by the camera lens 301 for an object in an object field is projected to the photosensitive surface of the image sensor 302 and then converted into an electrical signal. Then the electrical signal is converted into a digital image signal through analog-to-digital conversion, and the digital image signal is sent to a processor for processing. Then a processed signal is transmitted to a display (for example, a mobile phone screen). In this way, the image can be seen.

[0125] The camera lens 301 includes a plurality of lenses disposed along an optical axis, and a tube carrying the lenses. With a miniaturization and thinning design of a camera module, for example, with reference to FIG. 4, a size of the camera lens 301 along a height direction (for example, a Z direction in FIG. 4) becomes increasingly small, and a size of the camera lens 301 along a length direction (for example, an X direction in FIG. 4) becomes increasingly small, that is, a total track length of the camera lens becomes increasingly small. In addition, a camera lens that can implement a long focal length is increasingly popular, and a requirement for imaging quality and a magnification ratio is also increasingly high.

[0126] The following describes in detail a camera lens provided in this application with reference to accompanying drawings.

[0127] FIG. 5 is a diagram of a structure of a camera lens. Along a direction from an object field to an image field, the camera lens includes a first lens G11 having positive focal power, a prism G12, and a lens group G2 including a plurality of lenses. The prism G12 refracts, from a first optical axis X1 to a second optical axis X2 intersecting the first optical axis X1, light received from the first lens G11. In addition, an object-side surface of the first lens G11 is a convex surface, and an image-side surface of the first lens G11 is in contact with an object-side surface of the prism G12. The first lens G11 and the prism G12 herein form a refractive prism group G1.

[0128] The first lens G11 whose object-side surface is a convex surface converges light received from the object field and transmits the light to the prism G12. Then the prism G12 refracts the light converged by the first lens G11 from the first optical axis X1 to the second optical axis X2, to provide a bent optical axis for the entire camera lens. In this way, compared with an I-cut process in the conventional technology, a size of the camera lens along a Z direction can be reduced, and an amount of light entering the camera lens can also be ensured, to ensure imaging quality. Because the size of the camera lens along the Z direction can be reduced, a size of an entire camera module along the Z direction can be reduced.

[0129] Herein, the first lens G11 may be attached to the prism G12 in a plurality of manners. In some implementations, the prism G12 is made of a glass material, the first lens G11 is made of a plastic (plastic) material, and the first lens G11 may be attached to the prism G12 through a bonding layer. In some other implementations, both the prism G12 and the first lens G11 are made of a plastic material, and may be prepared by using an integral molding process, for example, an injection molding process. In some other implementations, both the prism G12 and the first lens G11 are made of a glass material, and may be prepared by using an integral molding process.

[0130] In this application, the first optical axis X1 may be perpendicular to the second optical axis X2, for example, as shown in FIG. 5. Certainly, there may be another included angle between the first optical axis X1 and the second optical axis X2. A deflection angle of the bent optical axis is not limited in this application.

[0131] In addition, in the camera lens provided in this embodiment of this application, a total focal length f of the camera lens is as follows: 14 mmf33 mm. In this way, light convergence and imaging quality can be improved, and imaging quality is good even in a long-focus scenario.

[0132] In some optional implementations, a ratio of an Abbe number V1 of the first lens G11 to an Abbe number V2 of the prism G12 is as follows:

[00007]$.Math.\frac{V1}{V2}.Math.3.$

[0133] Still with reference to FIG. 5, the lens group G2 including the plurality of lenses includes at least three lenses, and the plurality of lenses are sequentially disposed along the second optical axis X2. In addition, an image-side surface of a lens, in the lens group G2, that is close to the image field of the camera lens is a convex surface.

[0134] FIG. 5 shows an example in which the lens group G2 includes three lenses sequentially disposed along the second optical axis X2. The three lenses are a second lens G21, a third lens G22, and a fourth lens G23. An image-side surface of the fourth lens G23 is a convex surface. FIG. 6 is a diagram of an optical path corresponding to FIG. 5. The image-side surface of the lens, in the lens group G2, that is close to the image field of the camera lens is designed as a convex surface, so that light transmitted through the lens group G2 can be converged, to improve imaging quality.

[0135] In addition, both an object-side surface and an image-side surface of a lens, in the lens group G2, that is close to the prism G12 are aspheric (ASP) surfaces. The aspheric surface enables the lens to be made into a shape other than a spherical surface, to obtain a large quantity of control variables. This can reduce aberration and improve imaging quality, and can further reduce a quantity of lenses required, so that a total track length can be effectively reduced.

[0136] At least one lens in the lens group G2 in the camera lens provided in this application is a diffractive optical element (DOE). In this way, an optical path of light entering the DOE can be changed, so that light within different wavelength ranges is converged to a same intersection point. In this way, chromatic aberration of the prism G12 in a meridional direction (the T direction) and a sagittal direction (the S direction) is corrected, to optimize imaging quality and reduce the total track length.

[0137] The camera lens provided in this application further includes at least one zoom liquid lens, and the lens group G2 may include a first zoom liquid lens. In some other implementations, a second zoom liquid lens may be disposed on a side of the first lens G11 that is close to the object field.

[0138] FIG. 7 is a schematic diagram of a structure of a zoom liquid lens. The zoom liquid lens includes a drive cavity 1 and an optical cavity 2 that are connected. To be specific, liquid in the drive cavity 1 and liquid in the optical cavity 2 can flow between the two cavities. When the liquid in the optical cavity 2 changes, surface tension of a light exit surface 3 changes, and therefore curvature of the light exit surface 3 changes. A permanent magnet 4 and a coil 5 form a driving source, to drive the liquid in the optical cavity 2 and the liquid in the drive cavity 1 to flow between the cavities.

[0139] An operating principle of the zoom liquid lens shown in FIG. 7 may be explained as follows: For example, at a first moment, after a first current is supplied to the coil 5, a magnetic field generated by the coil 5 is different from a magnetic field generated by the permanent magnet 4, and the permanent magnet 4 is attracted to move downward, so that a size of the drive cavity 1 decreases, and the liquid in the drive cavity 1 flows to the optical cavity 2. In this case, the light exit surface 3 is deformed to form first curvature (indicated by a solid line), and a focal length of the zoom liquid lens is F1. At a second moment, after a second current is supplied to the coil 5, a magnetic field generated by the coil 5 is different from a magnetic field generated by the permanent magnet 4, and the permanent magnet 4 is attracted to move downward, so that a size of the drive cavity 1 decreases, and the liquid in the drive cavity 1 flows to the optical cavity 2. In this case, the light exit surface 3 is deformed to form second curvature (indicated by a dashed line), and a focal length of the zoom liquid lens is F2.

[0140] The zoom liquid lens is disposed in the camera lens, so that a total focal length of the camera lens can be changed for zooming. In this way, the camera lens can be used in a long-focus scenario and a short-focus scenario.

[0141] In addition, the camera lens further includes an aperture stop. The aperture stop is disposed on a side of the first lens G11 that is close to the object field, and an amount of light entering the camera lens is controlled by using the aperture stop.

[0142] In some optional implementations, the camera lens may further include an IR filter, and the IR filter can reduce or eliminate interference of environmental noise on the image sensor.

[0143] The following describes an embodiment of a camera lens in which a lens group G2 includes three lenses, an embodiment of a camera lens in which a lens group G2 includes four lenses, and an embodiment of a camera lens in which a lens group G2 includes five lenses.

[0144] In a camera lens shown in FIG. 5, a lens group G2 includes three lenses. The three lenses are a second lens G21, a third lens G22, and a fourth lens G23 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. An image-side surface of the fourth lens G23 is a convex surface, and an object-side surface of the fourth lens G23 is a concave surface. In addition, the camera lens further includes flat glass G3. In addition, the camera lens may further include an IR filter G4. The flat glass G3 is disposed on the image-side surface of the fourth lens G23, and the IR filter G4 is disposed on an image-side surface of the flat glass G3. The image-side surface of the fourth lens G23 is a convex surface, and the object-side surface of the fourth lens G23 is a concave surface.

[0145] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00008]$\left|\frac{f1}{f}\right|=0.538.$

[0146] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00009]$\left|\frac{f2}{f}\right|=0.803.$

[0147] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00010]$\left|\frac{f3}{f}\right|=0.595.$

[0148] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00011]$\left|\frac{f4}{f}\right|=0.532.$

[0149] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00012]$\frac{TTL}{f}=1.02.$

[0150] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00013]$\frac{IMH}{f}=0.088.$

[0151] Table 1-1 shows optical parameters of the camera lens.

TABLE-US-00001 TABLE 1-1 Optical parameter System focal length (F) 28.17 mm Aperture number (F/#) 3.79 Image height (IMH) 2.5 mm Total track length (TTL) 29.26 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0152] Table 1-2 shows optical parameters of optical components in the camera lens.

[0153] Radius indicates a curvature radius, Thickness indicates a thickness of the lens, nd indicates a refractive index of the lens, vd indicates an Abbe number of the lens, Infinity indicates that the curvature radius is infinite, R1 in G1 indicates an object-side surface of the first lens G11, R2 in G1 indicates an image-side surface of the first lens G11, A-01 in G1 indicates an object-side surface of the prism G12, B-03 in G1 indicates a reflective surface of the prism G12, C-02 in G1 indicates an image-side surface of the prism G12, R1 in each remaining lens is an object-side surface of the corresponding lens, and R2 in each remaining lens is an image-side surface of the corresponding lens.

TABLE-US-00002 TABLE 1-2 Radius Thickness nd vd G1 R1 9.4 d1 1.2 n1 1.618 v1 63.85 R2 Infinity d2 0 A-01 Infinity d3 4 n2 1.90 v2 31.05 B-03 Infinity d4 4 C-02 Infinity d5 0 G21 R1 10.224 d6 1.133 n1 1.76 v1 49.64 R2 6.137 d7 1.118 G22 R1 6.802 d8 0.876 n1 1.603 v1 65.45 R2 4.267 d9 0.313 G23 R1 4.347 d10 0.8 n1 1.74 v1 27.76 R2 7.672 d11 1.964 G3 R1 Infinity d12 13.903 n1 1.90 v1 37.05 R2 Infinity d13 0.03 G4 R1 Infinity d14 0.193 n1 1.51 v1 64.21 R2 Infinity d15 4.078

[0154] Table 1-3 shows aspheric coefficients of the lenses in Table 1-2.

[0155] K is a quadric surface constant, and A.sub.2, A.sub.3, A.sub.4, A.sub.5, A.sub.6, A.sub.7, and A.sub.8 are a second-order aspheric coefficient, a third-order aspheric coefficient, a fourth-order aspheric coefficient, a fifth-order aspheric coefficient, a sixth-order aspheric coefficient, a seventh-order aspheric coefficient, and an eighth-order aspheric coefficient respectively.

TABLE-US-00003 TABLE 1-3 Type K A2 A3 A4 A5 A6 A7 A8 G21 R1 Even-order 0.0 9.85E04 5.55E06 1.96E05 2.02E05 6.30E06 8.94E07 4.82E08 aspheric surface R2 Even-order 0.0 9.64E04 1.17E04 6.14E05 6.56E06 2.20E06 7.44E07 6.15E08 aspheric surface

[0156] It can be learned from Table 1-3 that the camera lens provided in this embodiment includes two aspheric surfaces that are even-order aspheric surfaces. In this embodiment, vector heights Z of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00014]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0157] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0158] FIG. 8a shows curves of axial aberration in the structure of the camera lens shown in FIG. 5 based on the data shown in Table 1-1, Table 1-2, and Table 1-3. In FIG. 8a, a horizontal coordinate indicates axial aberration, which may be measured in micrometers (m); and a vertical coordinate indicates a field of view, which may be measured in degrees. Five curves shown in FIG. 8a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 8a that axial aberration of light with different wavelengths is controlled within 0.1 m to 0.1 m, that is, controlled within a quite small range.

[0159] FIG. 8b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 5 based on the data shown in Table 1-1, Table 1-2, and Table 1-3. In FIG. 8b, a horizontal coordinate indicates lateral aberration, and a vertical coordinate indicates a field of view. Five curves shown in FIG. 8b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 8b that lateral aberration of light with different wavelengths is within the diffraction limit range.

[0160] FIG. 8c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 5 based on the data shown in Table 1-1, Table 1-2, and Table 1-3. FIG. 8d shows a curve of ideal distortion aberration. In FIG. 8c and FIG. 8d, a horizontal coordinate indicates distortion aberration, and a vertical coordinate indicates a field of view. It can be learned through comparison between FIG. 8c and FIG. 8d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes. This may be understood as follows: As shown in FIG. 8d, the ideal distortion aberration is approximately 0.05 m. As shown in FIG. 8c, distortion aberration of light with different wavelengths is controlled to be less than 0.01 m, where 0.01 m herein is obtained by 0.05 m2%. That is, the distortion aberration of the light with different wavelengths is controlled to be less than 2% of the ideal distortion aberration.

[0161] FIG. 9 is a diagram of a structure of another camera lens. A lens group G2 includes three lenses, and the three lenses are a second lens G21, a third lens G22, and a fourth lens G23 that are sequentially disposed along a second optical axis X2. In addition, the camera lens further includes flat glass G3. In addition, the camera lens may further include an IR filter G4.

[0162] In addition, the fourth lens G23 is a DOE, an image-side surface of the fourth lens G23 is a convex surface, and an object-side surface of the fourth lens G23 is a concave surface. In some optional implementations, the object-side surface of the fourth lens G23 is in contact with the third lens G22.

[0163] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00015]$\left|\frac{f1}{f}\right|=0.954.$

[0164] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00016]$\left|\frac{f2}{f}\right|=0.609.$

[0165] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00017]$\left|\frac{f3}{f}\right|=2.12.$

[0166] The fourth lens G23 has positive focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00018]$\left|\frac{f4}{f}\right|=0.883.$

[0167] A ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00019]$\frac{TTL}{f}=1.27.$

[0168] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00020]$\frac{IMH}{f}=0.095.$

[0169] Table 2-1 shows optical parameters of the camera lens.

TABLE-US-00004 TABLE 2-1 Optical parameter System focal length (F) 28.37 mm Aperture number (F/#) 4.07 Image height (IMH) 2.7 mm Total track length (TTL) 36.37 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0170] Table 2-2 shows optical parameters of optical components in the camera lens. A physical meaning represented by each optical parameter is the same as that in Table 1-2. Details are not described herein again.

TABLE-US-00005 TABLE 2-2 Radius Thickness nd vd G1 R1 23.158 d1 0.906 n1 1.851 v1 40.104 R2 Infinity d2 0 A-01 Infinity d3 4 n2 1.90 v2 37.05 B-03 Infinity d4 4 C-02 Infinity d5 2.008 G21 R1 3.453 d6 0.799 n1 1.639 v1 23.157 R2 5.460 d7 0.175 G22 R1 49.357 d8 0.679 n1 1.729 v1 54.673 G23 R1 49.357 d9 0.159 n1 1.689 v1 36.69 R2 18.169 d10 10 G3 R1 Infinity d12 13 n1 1.77 v1 49.61 R2 Infinity d13 1 G4 R1 Infinity d14 0.21 n1 1.51 v1 64.21 R2 Infinity d15 4.321

[0171] Table 2-3 shows aspheric coefficients of the lenses in Table 2-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface. The object-side surface of the fourth lens G23 is a binary 2 (Binary 2) diffractive surface, and the image-side surface of the fourth lens G23 is an even-order aspheric surface.

TABLE-US-00006 TABLE 2-3 Type K A2 A3 A4 A5 A6 A7 A8 G21 R1 Even-order 0.0 9.87E03 5.02E04 7.07E05 7.72E06 9.29E07 6.38E08 2.51E09 aspheric surface R2 Even-order 0.0 4.95E03 3.30E04 1.39E05 1.30E07 4.92E08 8.72E09 4.43E10 aspheric surface G23 R2 Even-order 0.0 1.10E03 4.68E05 1.29E05 1.54E06 1.54E06 7.64E08 1.28E09 aspheric surface

[0172] Table 2-4 shows a diffractive coefficient of the object-side surface of the fourth lens G23 in Table 2-3.

TABLE-US-00007 TABLE 2-4 Binary 2 Diffraction Norm Quadratic term Quartic term Sextic term Octic term order radius coefficient coefficient coefficient coefficient (Diffract Order) (Norm Radius) (coeff. on p{circumflex over ()}2) (coeff. on p{circumflex over ()}4) (coeff. on p{circumflex over ()}6) (coeff. on p{circumflex over ()}8) G4 R1 1 3 51.78 53.51 80.19 31.50

[0173] It can be learned from Table 2-3 that the camera lens provided in this embodiment includes three even-order aspheric surfaces. In this embodiment, vector heights z of all even-order aspheric surfaces may also be defined by using the following formula, but are not limited to the following formula:

[00021]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0174] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0175] In this embodiment, a vector height Z2 of the binary 2 diffractive surface may be defined by using the following formula:

[00022]$Z2=\frac{C{r}^2}{1+\sqrt{1-K{C}^2{r}^2}}+\underset{t-1}{\overset{8}{.Math.}}{a}_j{r}^{2i}+M\underset{J-1}{\overset{N}{.Math.}}{A}_j{p}^{2j},$

where [0176] M indicates a diffraction order, P indicates a phase distribution power, A indicates a phase distribution coefficient, C indicates vertex curvature of an aspheric surface, and r indicates a radial coordinate of the aspheric surface.

[0177] FIG. 10a shows curves of axial aberration in the structure of the camera lens shown in FIG. 9 based on the data shown in Table 2-1, Table 2-2, Table 2-3, and Table 2-4. Five curves shown in FIG. 10a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 10a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0178] FIG. 10b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 9 based on the data shown in Table 2-1, Table 2-2, Table 2-3, and Table 2-4. Five curves shown in FIG. 10b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 10b that lateral aberration of light with different wavelengths is within the diffraction range.

[0179] FIG. 10c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 9 based on the data shown in Table 2-1, Table 2-2, Table 2-3, and Table 2-4. FIG. 10d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 10c and FIG. 10d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0180] FIG. 11 is a diagram of a structure of another camera lens. A lens group G2 includes three lenses, and the three lenses are a second lens G21, a third lens G22, and a fourth lens G23 that are sequentially disposed along a second optical axis X2. In addition, the camera lens further includes flat glass G3. In addition, the camera lens may further include an IR filter G4. The flat glass G3 is disposed on the image-side surface of the fourth lens G23, and the IR filter G4 is disposed on an image-side surface of the flat glass G3. The image-side surface of the fourth lens G23 is a convex surface, and an object-side surface of the fourth lens G23 is a concave surface.

[0181] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00023]$.Math.\frac{f1}{f}.Math.=0.499.$

[0182] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00024]$.Math.\frac{f2}{f}.Math.=0.244.$

[0183] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00025]$.Math.\frac{f3}{f}.Math.=0.248.$

[0184] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00026]$.Math.\frac{f4}{f}.Math.=0.647.$

[0185] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00027]$\frac{TTL}{f}=1.18.$

[0186] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00028]$\frac{IMH}{f}=0.087.$

[0187] Table 3-1 shows optical parameters of the camera lens.

TABLE-US-00008 TABLE 3-1 Optical parameter System focal length (F) 28.58 mm Aperture number (F/#) 3.84 Image height (IMH) 2.5 mm Total track length (TTL) 33.67 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0188] Table 3-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00009 TABLE 3-2 Radius Thickness nd vd G1 R1 7.737 d1 1.279 n1 1.54 v1 55.98 R2 Infinity d2 0 A-01 Infinity d3 4.25 n2 1.90 v2 37.05 B-03 Infinity d4 4.25 C-02 Infinity d5 1.08 G21 R1 9.977 d6 0.998 n1 1.76 v1 49.64 R2 12.23 d7 0.766 G22 R1 238.706 d8 2.188 n1 1.60 v1 65.45 R2 4.35 d9 0.43 G23 R1 3.607 d10 1.552 n1 1.74 v1 27.76 R2 5.783 d12 3.007 G3 R1 Infinity d13 13.903 n1 1.90 v1 37.05 R2 Infinity d14 0.03 G4 R1 Infinity d15 0.193 n1 1.51 v1 64.21 R2 Infinity d16 5.264

[0189] Table 3-3 shows aspheric coefficients of the lenses in Table 3-2.

TABLE-US-00010 TABLE 3-3 Type K A2 A3 A4 A5 A6 A7 A8 G21 R1 Even- 0.0 6.10E03 4.86E04 1.24E04 5.23E05 1.52E05 2.28E06 1.41E07 order aspheric surface R2 Even- 0.0 5.78E03 3.56E04 8.84E06 1.28E05 2.00E06 1.33E07 1.01E09 order aspheric surface

[0190] It can be learned from Table 3-3 that the camera lens provided in this embodiment includes two even-order aspheric surfaces. In this embodiment, vector heights of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00029]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

[0191] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0192] FIG. 12a shows curves of axial aberration in the structure of the camera lens shown in FIG. 11 based on the data shown in Table 3-1, Table 3-2, and Table 3-3. Five curves shown in FIG. 12a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 12a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0193] FIG. 12b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 11 based on the data shown in Table 3-1, Table 3-2, and Table 3-3. Five curves shown in FIG. 12b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 12b that lateral aberration of light with different wavelengths is within the diffraction range.

[0194] FIG. 12c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 11 based on the data shown in Table 3-1, Table 3-2, and Table 3-3. FIG. 12d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 12c and FIG. 12d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0195] FIG. 13 is a diagram of a structure of another camera lens. A lens group G2 includes three lenses. The three lenses are a second lens G21, a third lens G22, and a fourth lens G23 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes flat glass G3. In addition, the camera lens may further include an IR filter G4.

[0196] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00030]$.Math.\frac{f1}{f}.Math.=0.631.$

[0197] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00031]$.Math.\frac{f2}{f}.Math.=0.192.$

[0198] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00032]$.Math.\frac{f3}{f}.Math.=0.201.$

[0199] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00033]$.Math.\frac{f4}{f}.Math.=0.924.$

[0200] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00034]$\frac{TTL}{f}=1.37.$

[0201] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00035]$\frac{IMH}{f}=0.088.$

[0202] Table 4-1 shows optical parameters of the camera lens.

TABLE-US-00011 TABLE 4-1 Optical parameter System focal length (F) 28.35 mm Aperture number (F/#) 3.87 Image height (IMH) 2.5 mm Total track length (TTL) 38.95 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0203] Table 4-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00012 TABLE 4-2 Radius Thickness nd vd G1 R1 9.7 d1 1.05 n1 1.54 v1 55.98 R2 Infinity d2 0.0 A-01 Infinity d3 3.95 B-03 Infinity d4 3.95 C-02 Infinity d5 1.662 G21 R1 3.003 d6 1.046 n1 1.76 v1 49.64 R2 12.095 d7 0.15 G22 R1 14.914 d8 2.3 n1 1.603 v1 65.45 R2 4.216 d9 0.203 G23 R1 4.114 d10 2.2 n1 1.74 v1 27.76 R2 6.402 d11 1.883 G3 R1 Infinity d12 13.9 n1 1.90 v1 37.05 R2 Infinity d13 0.03 G4 R1 Infinity d14 11.439 n1 1.51 v1 64.21

[0204] Table 4-3 shows aspheric coefficients of the lenses in Table 4-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface.

TABLE-US-00013 TABLE 4-3 Type K A2 A3 A4 A5 A6 A7 A8 G21 R1 Even- 0.0 1.71E02 1.55E03 3.97E04 1.22E04 2.89E05 3.63E06 1.88E07 order aspheric surface R2 Even- 0.0 1.04E02 9.04E04 9.71E05 2.42E05 5.07E06 5.52E07 2.38E08 order aspheric surface

[0205] It can be learned from Table 4-3 that the camera lens provided in this embodiment includes two even-order aspheric surfaces. In this embodiment, vector heights z of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00036]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0206] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0207] FIG. 14a shows curves of axial aberration in the structure of the camera lens shown in FIG. 13 based on the data shown in Table 4-1, Table 4-2, and Table 4-3. Five curves shown in FIG. 14a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 14a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0208] FIG. 14b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 13 based on the data shown in Table 4-1, Table 4-2, and Table 4-3. Five curves shown in FIG. 14b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 14b that lateral aberration of light with different wavelengths is within the diffraction range.

[0209] FIG. 14c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 13 based on the data shown in Table 4-1, Table 4-2, and Table 4-3. FIG. 14d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 14c and FIG. 14d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0210] FIG. 15 is a diagram of a structure of another camera lens. A lens group G2 includes three lenses. The three lenses are a second lens G21, a third lens G22, and a fourth lens G23 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. The fourth lens G23 is a zoom liquid lens. In addition, the camera lens further includes flat glass G3. In addition, the camera lens may further include an IR filter G4.

[0211] An image-side surface of the third lens G22 is a convex surface. The image-side surface of the third lens G22 is designed as a convex surface, so that light can be converged, to further improve image quality.

[0212] An image-side surface of the fourth lens G23 is a convex surface, and an object-side surface of the fourth lens G23 is a concave surface.

[0213] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00037]$.Math.\frac{f1}{f}.Math.=0.867.$

[0214] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00038]$.Math.\frac{f2}{f}.Math.=0.766.$

[0215] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00039]$.Math.\frac{f3}{f}.Math.=2.136.$

[0216] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00040]$1.45<.Math.\frac{f4}{f}.Math.<2.38.$

[0217] An aperture of the camera lens is as follows: 3.4<F/#<5.

[0218] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00041]$0.980<\frac{\mathrm{TTL}}{f}<1.356.$

[0219] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00042]$0.075<\frac{\mathrm{IMH}}{f}<0\text{.12}.$

[0220] Table 5-1 shows optical parameters of the camera lens.

TABLE-US-00014 TABLE 5-1 Optical parameter System focal length (F) 27.997 mm, 24.007 mm, and 32.998 mm Aperture number (F/#) 4.13, 3.44, and 4.98 Image height (IMH) 2.5 mm Total track length (TTL) 32.54 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0221] Table 5-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00015 TABLE 5-2 Radius Thickness nd vd G1 R1 18.833 d1 1.021 n1 1.54 v1 55.98 R2 Infinity d2 0 A-01 Infinity d3 4 n2 1.90 v2 37.05 B-03 Infinity d4 4 C-02 Infinity d5 0.8 G21 R1 7.356 d6 1.55 n1 1.63 v1 23.51 R2 21.03 d7 0.936 G22 R1 93.407 d8 1.347 n1 1.72 v1 54.67 R2 62.324 d9 0.319 G23 R1 Infinity d10 0.2 n1 1.51 v1 64.21 R2 Infinity d11 0.5 n1 1.291 v1 108.49 R3 Same as that d12 6.059 in Table 5-3 G3 R1 Infinity d13 13 n1 1.90 v1 37.05 R2 Infinity d14 1 G4 R1 Infinity d15 0.21 n1 1.51 v1 64.21 R2 Infinity d16 2.61

[0222] Table 5-3 shows a curvature radius of the zoom liquid lens and a corresponding focal length.

TABLE-US-00016 TABLE 5-3 Curvature radius R3 and focal length of the zoom liquid lens CONF1 CONF2 CONF3 R3 14.345 22.857 10.186 Total focal length 27.99 mm 33.001 mm 24.008 mm

[0223] Table 5-4 shows aspheric coefficients of the lenses in Table 5-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface.

TABLE-US-00017 TABLE 5-4 Type K A2 A3 A4 A5 A6 A7 A8 G21 R1 Even- 0.0 2.35E03 1.65E04 2.77E05 3.07E06 1.36E07 0.00E+00 0.00E+00 order aspheric surface R2 Even- 0.0 1.78E03 8.58E05 5.08E06 1.84E06 5.66E07 5.84E08 2.13E09 order aspheric surface

[0224] Similarly, in this embodiment, vector heights Z of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00043]$Z=\frac{{\mathrm{CX}}^2}{1+\sqrt{1-{\mathrm{KC}}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0225] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0226] FIG. 16a shows curves of axial aberration in the structure of the camera lens shown in FIG. 15 based on the data shown in Table 5-1, Table 5-2, Table 5-3, and Table 5-4. Five curves shown in FIG. 16a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 16a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0227] FIG. 16b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 15 based on the data shown in Table 5-1, Table 5-2, Table 5-3, and Table 5-4. Five curves shown in FIG. 16b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 16b that lateral aberration of light with different wavelengths is within the diffraction range.

[0228] FIG. 16c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 15 based on the data shown in Table 5-1, Table 5-2, Table 5-3, and Table 5-4. FIG. 16d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 16c and FIG. 16d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0229] In the camera lenses shown in FIG. 5, FIG. 9, FIG. 11, FIG. 13, and FIG. 15, the lens group G2 includes three lenses, and these camera lens structures may be referred to as combined three-piece lens groups.

[0230] In these three-piece lens groups, the ratio of the focal length f2 of the second lens to the total focal length f of the camera lens is as follows:

[00044]$0\text{.1}.Math.\frac{f2}{f}.Math.0.9.$

[0231] FIG. 17 is a diagram of a structure of another camera lens. A lens group G2 includes four lenses. The three lenses are a second lens G21, a third lens G22, a fourth lens G23, and a fifth lens G24 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes an IR filter G3. An image-side surface of the fifth lens G24 is a convex surface.

[0232] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00045]$.Math.\frac{f1}{f}.Math.=0.631.$

[0233] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00046]$.Math.\frac{f2}{f}.Math.=0.192.$

[0234] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00047]$.Math.\frac{f3}{f}.Math.=0.201.$

[0235] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00048]$.Math.\frac{f4}{f}.Math.=0.924.$

[0236] The fifth lens G24 has positive focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00049]$.Math.\frac{f4}{f}.Math.=0.33.$

[0237] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00050]$\frac{TTL}{f}=1.37.$

[0238] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00051]$\frac{IMH}{f}=0.088.$

[0239] Table 6-1 shows optical parameters of the camera lens.

TABLE-US-00018 TABLE 6-1 Optical parameter System focal length (F) 28.40 mm Aperture number (F/#) 3.81 Image height (IMH) 2.5 mm Total track length (TTL) 25.74 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0240] Table 6-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00019 TABLE 6-2 Radius Thickness nd vd G1 R 9.4 d1 1.2 n1 1.61 v1 63.8 R2 Infinity d2 0 A-01 Infinity d3 4 n1 1.90 v1 37.8 B-03 Infinity d4 4 C-02 Infinity d5 0.662 G21 R1 7.453 d6 1.02 n1 1.76 v1 49.64 R2 7.081 d7 0.075 G22 R1 25.59 d8 0.407 n1 1.603 v1 65.45 R2 11.27 d9 0.714 G23 R1 23.928 d10 0.602 n1 1.74 v1 27.76 R2 6.549 d11 0.930 G24 R1 9.099 d12 1.311 n1 1.90 v1 37.05 R2 80 d13 0.951 G3 R1 Infinity d14 0.193 n1 1.51 v1 64.21 R2 Infinity d15 14.877

[0241] Table 6-3 shows aspheric coefficients of the lenses in Table 6-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface.

TABLE-US-00020 TABLE 6-3 Type K A2 A3 A4 A5 A6 A7 A8 G21 R1 Even- 0.0 2.07E04 3.21E05 6.01E06 2.44E06 4.71E07 4.25E08 1.46E09 order aspheric surface R2 Even- 0.0 1.15E04 9.43E06 1.92E06 3.72E07 1.58E07 1.75E08 6.43E10 order aspheric surface

[0242] It can be learned from Table 6-3 that the camera lens provided in this embodiment includes two even-order aspheric surfaces. In this embodiment, vector heights z of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00052]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0243] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0244] FIG. 18a shows curves of axial aberration in the structure of the camera lens shown in FIG. 17 based on the data shown in Table 6-1, Table 6-2, and Table 6-3. Five curves shown in FIG. 18a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 18a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0245] FIG. 18b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 17 based on the data shown in Table 6-1, Table 6-2, and Table 6-3. Five curves shown in FIG. 18b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 18b that lateral aberration of light with different wavelengths is within the diffraction range.

[0246] FIG. 19 is a diagram of a structure of another camera lens. A lens group G2 includes four lenses. The three lenses are a second lens G21, a third lens G22, a fourth lens G23, and a fifth lens G24 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes an IR filter G3. An object-side surface of the fifth lens G24 is a convex surface.

[0247] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00053]$.Math.\frac{f1}{f}.Math.=0.533.$

[0248] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00054]$.Math.\frac{f2}{f}.Math.=1.261.$

[0249] The third lens G22 has negative focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00055]$.Math.\frac{f3}{f}.Math.=1.431.$

[0250] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00056]$.Math.\frac{f4}{f}.Math.=0.226.$

[0251] The fifth lens G24 has positive focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00057]$.Math.\frac{f5}{f}.Math.=0.242.$

[0252] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00058]$\frac{TTL}{f}=0.912.$

[0253] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00059]$\frac{IMH}{f}=0.088.$

[0254] Table 7-1 shows optical parameters of the camera lens.

TABLE-US-00021 TABLE 7-1 Optical parameter System focal length (F) 28.4 mm Aperture number (F/#) 3.81 Image height (IMH) 2.5 mm Total track length (TTL) 25.6 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0255] Table 7-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00022 TABLE 7-2 Radius Thickness nd vd G1 R1 d1 1.2 n1 1.618 v1 63.85 R2 Infinity d2 0 A-01 Infinity d3 4 n2 1.90 v2 31.05 B-03 Infinity d4 4 C-02 Infinity d5 0.662 G21 R1 62.0 d6 0.548 n1 1.76 v1 49.64 R2 50 d7 0.075 G22 R1 21 d8 0.447 n1 1.603 v1 65.45 R2 11.233 d9 0.895 G23 R1 19.726 d10 0.644 n1 1.74 v1 27.76 R2 6.409 d11 0.525 G24 R1 8.175 d12 1.441 n1 1.90 v1 37.05 R2 20 d13 0.957 G3 R1 Infinity d14 0.193 n1 1.51 v1 64.21 R2 Infinity d15 15.231

[0256] Table 7-3 shows aspheric coefficients of the lenses in Table 7-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface.

TABLE-US-00023 TABLE 7-3 Type K A2 A3 A4 A5 A6 A7 A8 G21 R1 Even- 0.0 9.53E04 1.04E04 3.76E05 1.10E05 1.85E06 1.55E07 5.09E09 order aspheric surface R2 Even- 0.0 8.99E04 6.56E05 2.43E05 8.43E06 1.62E06 1.48E07 5.20E09 order aspheric surface

[0257] It can be learned from Table 7-3 that the camera lens provided in this embodiment includes two aspheric surfaces. In this embodiment, vector heights z of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00060]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$ [0258] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0259] FIG. 20a shows curves of axial aberration in the structure of the camera lens shown in FIG. 19 based on the data shown in Table 7-1, Table 7-2, and Table 7-3. Five curves shown in FIG. 20a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 20a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0260] FIG. 20b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 19 based on the data shown in Table 7-1, Table 7-2, and Table 7-3. Five curves shown in FIG. 20b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 20b that lateral aberration of light with different wavelengths is within the diffraction range.

[0261] FIG. 20c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 19 based on the data shown in Table 7-1, Table 7-2, and Table 7-3. FIG. 20d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 20c and FIG. 20d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0262] FIG. 21 is a diagram of a structure of another camera lens. A lens group G2 includes four lenses. The three lenses are a second lens G21, a third lens G22, a fourth lens G23, and a fifth lens G24 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes an IR filter G3. An image-side surface of the fifth lens G24 is a convex surface.

[0263] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00061]$.Math.\frac{f1}{f}.Math.=0.534.$

[0264] The second lens G21 has positive focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00062]$.Math.\frac{f2}{f}.Math.=0.594.$

[0265] The third lens G22 has negative focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00063]$.Math.\frac{f3}{f}.Math.=1.432.$

[0266] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00064]$.Math.\frac{f4}{f}.Math.=0.167.$

[0267] The fifth lens G24 has positive focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00065]$.Math.\frac{f5}{f}.Math.=0.416.$

[0268] In addition, a ratio of a total track length (TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00066]$\frac{TTL}{f}=0.861.$

[0269] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00067]$\frac{IMH}{f}=0.095.$

[0270] Table 8-1 shows optical parameters of the camera lens.

TABLE-US-00024 TABLE 8-1 Optical parameter System focal length (F) 28.39 mm Aperture number (F/#) 3.81 Image height (IMH) 2.5 mm Total track length (TTL) 24.4 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0271] Table 8-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00025 TABLE 8-2 Radius Thickness nd vd G1 R1 9.4 d1 1.2 n1 1.851 v1 40.104 R2 Infinity d2 0 A-01 Infinity d3 4 n2 1.90 v2 37.05 B-03 Infinity d4 4 C-02 Infinity d5 0.662 G21 R1 20 d6 0.963 n1 1.768 v1 49.64 R2 36.374 d7 0.075 G22 R1 21 d8 0.446 n1 1.60 v1 65.45 R2 11.233 d9 0.861 G23 R1 8.455 d10 0.724 n1 1.74 v1 27.76 R2 6.321 2.751 G24 R1 22.232 d12 1.43 n1 1.90 v1 37.05 R2 20 d13 1.001 G3 R1 Infinity d14 0.193 n1 1.51 v1 64.21 R2 Infinity d15 11.346

[0272] Table 8-3 shows aspheric coefficients of the lenses in Table 8-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface.

TABLE-US-00026 TABLE 8-3 Type K A2 A3 A4 A5 G21 R1 Even- 0.0 2.16E03 6.13E05 2.59E05 3.10E06 order aspheric surface R2 Even- 0.0 2.83E03 2.66E06 4.73E05 9.72E06 order aspheric surface Type K A6 A7 A8 R1 Even- 0.0 3.13E07 1.43E08 1.33E09 order aspheric surface R2 Even- 0.0 1.17E06 6.05E08 1.25E09 order aspheric surface

[0273] It can be learned from Table 8-3 that the camera lens provided in this embodiment includes two aspheric surfaces. In this embodiment, vector heights z of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00068]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0274] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0275] FIG. 22a shows curves of axial aberration in the structure of the camera lens shown in FIG. 21 based on the data shown in Table 8-1, Table 8-2, and Table 8-3. Five curves shown in FIG. 22a are curves of axial aberration corresponding to designed wavelengths of 850 nm, 810 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 22a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0276] FIG. 22b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 21 based on the data shown in Table 8-1, Table 8-2, and Table 8-3. Five curves shown in FIG. 22b are curves of lateral aberration corresponding to designed wavelengths of 850 nm, 810 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 22b that lateral aberration of light with different wavelengths is within the diffraction range.

[0277] FIG. 22c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 21 based on the data shown in Table 8-1, Table 8-2, and Table 8-3. FIG. 22d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 22c and FIG. 22d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0278] FIG. 23 is a diagram of a structure of another camera lens. A lens group G2 includes four lenses. The three lenses are a second lens G21, a third lens G22, a fourth lens G23, and a fifth lens G24 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes a prism group G3 and an IR filter G4. The fourth lens G23 is a DOE.

[0279] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00069]$.Math.\frac{f1}{f}.Math.=0.446.$

[0280] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00070]$.Math.\frac{f2}{f}.Math.=0.286.$

[0281] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00071]$.Math.\frac{f3}{f}.Math.=0.967.$

[0282] The fourth lens G23 has positive focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00072]$.Math.\frac{f4}{f}.Math.=0.364.$

[0283] The fifth lens G24 has negative focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00073]$.Math.\frac{f5}{f}.Math.=0.441.$

[0284] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00074]$\frac{TTL}{f}=1.032.$

[0285] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00075]$\frac{IMH}{f}=0.089.$

[0286] Table 9-1 shows optical parameters of the camera lens.

TABLE-US-00027 TABLE 9-1 Optical parameter System focal length (F) 28.005 mm Aperture number (F/#) 4.06 Image height (IMH) 2.5 mm Total track length (TTL) 28.9 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0287] Table 9-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00028 TABLE 9-2 Radius Thickness nd vd G1 R1 8.547 d1 1.2 n1 1.62 v1 63.8 R2 Infinity d2 0 A-01 Infinity d3 4 n2 1.90 v2 37.05 B-03 Infinity d4 4 C-02 Infinity d5 0.86 G21 R1 10.224 d6 0.439 n1 1.768 v1 49.64 R2 3.782 d7 1.214 G22 R1 6.371 d8 0.876 n1 1.60 v1 65.45 R2 9.892 d9 0.3 G23 R1 21.006 d10 0.313 n1 1.63 v1 24.3 R2 Infinity d11 0.8 n1 1.51 v1 64.21 R3 7.591 d12 0.8 G24 R1 3.998 d13 0.8 n1 1.74 v1 27.8 R2 7.672 d14 1.893 G3 R1 Infinity d15 13.903 n1 1.90 v1 37.5 R2 Infinity d16 0.03 G4 R1 Infinity d17 0.193 n1 1.51 v1 64.21 R2 Infinity d18 2.481

[0288] Table 9-3 shows aspheric coefficients of the lenses in Table 9-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface. The object-side surface of the fourth lens G23 is a binary 2 diffractive surface.

TABLE-US-00029 TABLE 9-3 Type K A2 A3 A4 A5 G21 R1 Even- 0.0 1.99E02 3.30E03 3.21E04 1.35E05 order aspheric surface R2 Even- 0.0 2.48E02 4.09E03 5.43E04 1.37E05 order aspheric surface Type K A6 A7 A8 R1 Even- 0.0 9.09E06 1.15E06 5.09E08 order aspheric surface R2 Even- 0.0 8.38E06 1.38E06 7.03E08 order aspheric surface

[0289] Table 9-4 shows a diffractive coefficient of the fourth lens G23 in Table 9-3.

TABLE-US-00030 TABLE 9-4 Binary 2 Diffraction Norm order radius (Diffract (Norm coeff. coeff. coeff. coeff. Order) Radius) on p{circumflex over ()}2 on p{circumflex over ()}4 on p{circumflex over ()}6 on p{circumflex over ()}8 G4 1 2.3 42.352 16.633 4.962 0 R1

[0290] It can be learned from Table 9-3 that the camera lens provided in this embodiment includes three aspheric surfaces. In this embodiment, vector heights z of all even-order aspheric surfaces may also be defined by using the following formula, but are not limited to the following formula:

[00076]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0291] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0292] In this embodiment, a vector height Z2 of the binary 2 diffractive surface may be defined by using the following formula:

[00077]$Z2=\frac{C{r}^2}{1+\sqrt{1-K{C}^2{r}^2}}+\underset{i=1}{\overset{8}{.Math.}}{a}_i{r}^{2i}+M\underset{J=1}{\overset{N}{.Math.}}{A}_j{p}^{2j},$

where [0293] M indicates a diffraction order, P indicates a phase distribution power, A indicates a phase distribution coefficient, C indicates vertex curvature of an aspheric surface, and r indicates a radial coordinate of the aspheric surface.

[0294] FIG. 24a shows curves of axial aberration in the structure of the camera lens shown in FIG. 23 based on the data shown in Table 9-1, Table 9-2, Table 9-3, and Table 9-4. Five curves shown in FIG. 24a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 624 nm, 555 nm, 524 nm, and 470 nm respectively. It can be learned from FIG. 24a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0295] FIG. 24b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 23 based on the data shown in Table 9-1, Table 9-2, Table 9-3, and Table 9-4. Five curves shown in FIG. 24b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 624 nm, 555 nm, 524 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 24b that lateral aberration of light with different wavelengths is within the diffraction range.

[0296] FIG. 24c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 23 based on the data shown in Table 9-1, Table 9-2, Table 9-3, and Table 9-4. FIG. 24d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 24c and FIG. 24d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0297] FIG. 25 is a diagram of a structure of another camera lens. A lens group G2 includes four lenses. The three lenses are a second lens G21, a third lens G22, a fourth lens G23, and a fifth lens G24 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes flat glass G3 and an IR filter G4. The fourth lens G23 is a DOE. The fifth lens G24 is a zoom liquid lens. An image-side surface of the fifth lens G24 is a convex surface.

[0298] A ratio of a focal length f of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00078]$0.55<.Math.\frac{f1}{f}.Math.<0.61.$

[0299] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00079]$0.27<.Math.\frac{f2}{f}.Math.<0.3.$

[0300] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00080]$0.29<.Math.\frac{f3}{f}.Math.<0.33.$

[0301] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00081]$0.67<.Math.\frac{f4}{f}.Math.<0.75.$

[0302] The fifth lens G24 has positive focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00082]$.Math.\frac{f5}{f}.Math.<3.65.$

[0303] An aperture of the camera lens is as follows: 3.35<F/#<3.7.

[0304] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length of the camera lens is as follows:

[00083]$0.98<\frac{\mathrm{TTL}}{f}<1\text{.05}.$

[0305] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00084]$0.09<\frac{\mathrm{IMH}}{f}<0.1.$

[0306] Table 10-1 shows optical parameters of the camera lens.

TABLE-US-00031 TABLE 10-1 Optical parameter System focal length (F) 24.8 mm < F < 27.4 mm Aperture number (F/#) 3.35 < F/# < 3.74 Image height (IMH) 2.5 mm Total track length (TTL) 26 mm < TTL < 27 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0307] Table 10-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00032 TABLE 10-2 Radius Thickness nd vd G1 R1 9.4 d1 1.2 n1 1.62 v1 63.8 R2 Infinity d2 0 A-01 Infinity d3 4 n2 1.90 v2 37.05 B-03 Infinity d4 4 C-02 Infinity d5 0.862 G21 R1 10.224 d6 1.133 n1 1.768 v1 49.64 R2 3.497 d7 1.133 G22 R1 6.337 d8 0.876 n1 1.60 v1 65.4 R2 19.965 d9 0.313 G23 R1 15.128 d10 0.8 n1 1.74 v1 27.76 R2 7.039 d11 3.354 G24 R1 Infinity d12 0.2 n1 1.51 v1 64.21 R2 Infinity d13 0.3 n1 1.29 v1 108.49 R3 Infinity or 25.28 d14 0.5 G3 R1 Infinity d15 10 n1 1.90 v1 37.5 R2 Infinity d16 0.03 G4 R1 Infinity d17 0.193 n1 1.51 v1 64.21 R2 Infinity d18 2.403

[0308] Table 10-3 shows aspheric coefficients of the lenses in Table 10-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface.

TABLE-US-00033 TABLE 10-3 Type K A2 A3 A4 A5 G21 R1 Even- 0.0 5.22E03 2.21E04 1.10E05 3.91E06 order aspheric surface R2 Even- 0.0 8.51E03 2.56E04 2.89E05 2.11E05 order aspheric surface Type K A6 A7 A8 R1 Even- 0.0 2.40E07 3.69E08 4.24E09 order aspheric surface R2 Even- 0.0 4.29E06 4.08E07 1.30E08 order aspheric surface

[0309] Similarly, in this embodiment, vector heights z of all even-order aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00085]$Z=\frac{{\mathrm{CX}}^2}{1+\sqrt{1-{\mathrm{KC}}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0310] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0311] FIG. 26a shows curves of axial aberration in the structure of the camera lens shown in FIG. 25 based on the data shown in Table 10-1, Table 10-2, Table 10-3, and Table 10-4. Five curves shown in FIG. 26a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 26a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0312] FIG. 26b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 25 based on the data shown in Table 10-1, Table 10-2, Table 10-3, and Table 10-4. Five curves shown in FIG. 26b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 26b that lateral aberration of light with different wavelengths is within the diffraction range.

[0313] FIG. 26c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 25 based on the data shown in Table 10-1, Table 10-2, Table 10-3, and Table 10-4. FIG. 26d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 26c and FIG. 26d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0314] In the camera lenses shown in FIG. 17, FIG. 19, FIG. 21, FIG. 23, and FIG. 25, the lens group G2 includes four lenses, and these camera lens structures may be referred to as combined four-piece lens groups.

[0315] In the foregoing combined four-piece lens groups, the ratio of the focal length f2 of the second lens to the total focal length f of the camera lens is as follows:

[00086]$0.2.Math.\frac{f2}{f}.Math.1.3.$

[0316] FIG. 27 is a diagram of a structure of another camera lens. A lens group G2 includes five lenses. The five lenses are a second lens G21, a third lens G22, a fourth lens G23, a fifth lens G24, and a sixth lens G25 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes an IR filter G3. An image-side surface of the fifth lens G24 is a convex surface, and an image-side surface of the sixth lens G25 is a convex surface.

[0317] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00087]$.Math.\frac{f1}{f}.Math.=1.297.$

[0318] The second lens G21 has positive focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00088]$.Math.\frac{f2}{f}.Math.=0.317.$

[0319] The third lens G22 has negative focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00089]$.Math.\frac{f3}{f}.Math.=0.253.$

[0320] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00090]$.Math.\frac{f4}{f}.Math.=0.64.$

[0321] The fifth lens G24 has positive focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00091]$.Math.\frac{f5}{f}.Math.=0.185.$

[0322] The sixth lens G25 has negative focal power, and a ratio of a focal length f6 of the sixth lens G25 to the total focal length f of the camera lens is as follows:

[00092]$.Math.\frac{f6}{f}.Math.=0.268.$

[0323] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00093]$\frac{\mathrm{TTL}}{f}=1.036.$

[0324] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00094]$\frac{\mathrm{IMH}}{f}=0.157.$

[0325] Table 11-1 shows optical parameters of the camera lens.

TABLE-US-00034 TABLE 11-1 Optical parameter System focal length (F) 14.37 mm Aperture number (F/#) 3.34 Image height (IMH) 2.25 mm Total track length (TTL) 14.9 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0326] Table 11-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00035 TABLE 11-2 Radius Thickness nd vd G1 R1 16.873 d1 0.5 n1 1.90 v1 37.05 R2 Infinity d2 0 A-01 Infinity d3 2.2 n2 1.90 v2 37.05 B-03 Infinity d4 2.2 C-02 Infinity d5 2.03 G21 R1 2.588 d6 1.3 n1 1.54 v1 55.86 R2 53.188 d7 0.25 G22 R1 5.344 d8 0.297 n1 1.650 v1 21.53 R2 4.396 d9 1.125 G23 R1 29.197 d10 1.137 n1 1.54 v1 55.86 R2 4.23 d11 1.13 G24 R1 7.644 d13 1.137 n1 1.65 v1 21.53 R2 1.506 d14 0.091 G25 R1 2.259 d15 1.059 n1 1.65 v1 21.53 R2 25.142 d16 1.00 G3 R1 Infinity d17 0.21 n1 1.51 v1 64.16 R2 Infinity d18 1.97

[0327] Table 11-3 shows aspheric coefficients of the lenses in Table 11-2.

TABLE-US-00036 TABLE 11-3 Norm Type K Rad a2 a3 a4 a5 G21 R1 EA 0.00 1.206 5.02E03 1.28E03 1.90E03 5.61E06 R2 EA 44.46 1.206 2.97E02 2.07E02 3.44E03 5.49E05 G22 R1 EA 50.00 1.206 2.09E02 5.48E02 3.51E02 6.06E03 R2 EA 6.64 1.206 6.20E02 2.27E03 7.15E02 3.58E02 G23 R1 EA 0.00 1.206 8.54E02 3.57E02 2.95E03 2.11E04 R2 EA 27.75 1.206 7.11E02 5.93E02 1.84E02 7.61E05 G24 R1 EA 0.00 1.206 8.72E02 2.19E02 2.77E03 9.68E04 R2 EA 12.05 1.206 1.46E02 1.74E02 2.50E03 1.03E04 G25 R1 EA 47.55 1.206 2.57E02 9.35E02 2.88E02 2.21E03 R2 EA 45.97 1.206 2.69E02 5.91E03 2.38E03 9.77E05

[0328] The camera lens includes a total of 10 extended aspheric surfaces (Extended Asphere, EA).

[0329] In this embodiment, vector heights Z of all extended aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00095]$Z=\frac{{\mathrm{Cr}}^2}{1+\sqrt{1-\left(K+1\right)C^2{r}^2}}+a_1{r}^2+a_2{r}^4+a_3{r}^6+a_4{r}^8+a_5{r}^{10}+.Math.,$

where [0330] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, C indicates vertex curvature of the aspheric surface, and a.sub.1, a.sub.2, a.sub.3, and the like are aspheric coefficients.

[0331] FIG. 28a shows curves of axial aberration in the structure of the camera lens shown in FIG. 27 based on the data shown in Table 11-1, Table 11-2, and Table 11-3. Five curves shown in FIG. 28a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 28a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0332] FIG. 28b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 27 based on the data shown in Table 11-1, Table 11-2, and Table 11-3. Five curves shown in FIG. 28b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 28b that lateral aberration of light with different wavelengths is within the diffraction range.

[0333] FIG. 28c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 27 based on the data shown in Table 11-1, Table 11-2, and Table 11-3. FIG. 28d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 28c and FIG. 28d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0334] FIG. 29 is a diagram of a structure of another camera lens. A lens group G2 includes five lenses. The five lenses are a second lens G21, a third lens G22, a fourth lens G23, a fifth lens G24, and a sixth lens G25 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes an IR filter G3. An image-side surface of the fifth lens G24 is a convex surface.

[0335] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00096]$.Math.\frac{f1}{f}.Math.=2.536.$

[0336] The second lens G21 has positive focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length of the camera lens is as follows:

[00097]$.Math.\frac{f2}{f}.Math.=0.379.$

[0337] The third lens G22 has negative focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00098]$.Math.\frac{f3}{f}.Math.=0.489.$

[0338] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00099]$.Math.\frac{f4}{f}.Math.=0.792.$

[0339] The fifth lens G24 has positive focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00100]$.Math.\frac{f5}{f}.Math.=0.279.$

[0340] The sixth lens G25 has negative focal power, and a ratio of a focal length f6 of the sixth lens G25 to the total focal length f of the camera lens is as follows:

[00101]$.Math.\frac{f6}{f}.Math.=0.361.$

[0341] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00102]$\frac{\mathrm{TTL}}{f}=1.14.$

[0342] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00103]$\frac{\mathrm{IMH}}{f}=0.156.$

[0343] Table 12-1 shows optical parameters of the camera lens.

TABLE-US-00037 TABLE 12-1 Optical parameter System focal length (F) 14.44 mm Aperture number (F/#) 3.38 Image height (IMH) 2.25 mm Total track length (TTL) 15.9 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0344] Table 12-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00038 TABLE 12-2 Radius Thickness nd vd G1 R1 24.818 d1 0.5 n1 1.63 v1 24 R2 Infinity d2 0.1 n1 1.90 v1 37.05 Binary 2 A-01 Infinity d3 2.2 n2 1.90 v2 37.05 B-03 Infinity d4 2.2 C-02 Infinity d5 2.03 G21 R1 2.734 d6 1.3 n1 1.54 v1 55.86 R2 26.953 d7 0.25 G22 R1 87.477 d8 0.297 n1 1.650 v1 21.53 R2 4.904 d9 1.211 G23 R1 29.01 d10 0.343 n1 1.54 v1 55.86 R2 5.116 d11 1.096 G24 R1 4.551 d13 0.984 n1 1.65 v1 21.53 R2 1.816 d14 0.086 G25 R1 2.983 d15 0.574 n1 1.65 v1 21.53 R2 25.142 d16 1.013 G3 R1 Infinity d17 0.21 n1 1.51 v1 64.16 R2 Infinity d18 4.397

[0345] Table 12-3 shows aspheric coefficients of the lenses in Table 12-2.

TABLE-US-00039 TABLE 12-3 Norm Type K Rad a2 a3 a4 a5 G21 R1 EA 0.00 1.206 6.6890E03 9.5986E05 5.0331E04 5.6132E06 R2 EA 44.46 1.206 1.8564E02 9.2626E03 1.4363E03 5.4934E05 G22 R1 EA 50.00 1.206 2.6173E02 3.4575E02 1.5572E02 1.8848E03 R2 EA 6.64 1.206 1.9182E02 4.7482E02 1.1398E03 2.3351E03 G23 R1 EA 0.00 1.206 4.8108E02 1.1214E02 5.4199E03 2.1081E04 R2 EA 27.75 1.206 2.6036E02 4.0110E02 1.5614E02 7.6137E05 G24 R1 EA 0.00 1.206 5.7529E02 2.4011E02 4.2569E05 9.6843E04 R2 EA 12.05 1.206 5.8719E02 4.0044E03 1.3005E03 1.0331E04 G25 R1 EA 47.55 1.206 5.8848E02 6.0604E02 2.5079E02 2.2110E03 R2 EA 45.97 1.206 5.8953E02 1.0575E03 2.3201E03 9.7718E05

[0346] The camera lens includes a total of 10 extended aspheric surfaces.

[0347] In this embodiment, vector heights z of all extended aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00104]$Z=\frac{{\mathrm{Cr}}^2}{1+\sqrt{1-\left(K+1\right)C^2{r}^2}}+a_1{r}^2+a_2{r}^4+a_3{r}^6+a_4{r}^8+a_5{r}^{10}+.Math.,$

where [0348] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, C indicates vertex curvature of the aspheric surface, and a.sub.1, a.sub.2, a.sub.3, and the like are aspheric coefficients.

[0349] FIG. 30a shows curves of axial aberration in the structure of the camera lens shown in FIG. 29 based on the data shown in Table 12-1, Table 12-2, and Table 12-3. Five curves shown in FIG. 30a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 30a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0350] FIG. 30b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 29 based on the data shown in Table 12-1, Table 12-2, and Table 12-3. Five curves shown in FIG. 30b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 30b that lateral aberration of light with different wavelengths is within the diffraction range.

[0351] FIG. 30c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 29 based on the data shown in Table 12-1, Table 12-2, and Table 12-3. FIG. 30d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 30c and FIG. 30d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0352] FIG. 31 is a diagram of a structure of another camera lens. A lens group G2 includes five lenses. The five lenses are a second lens G21, a third lens G22, a fourth lens G23, a fifth lens G24, and a sixth lens G25 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes an IR filter G3. In addition, the camera lens further includes a zoom liquid lens G0. The zoom liquid lens G0 is disposed on a side of an image-side surface of the first lens G11. An image-side surface of the sixth lens G25 is a convex surface.

[0353] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00105]$8\text{.8}<.Math.\frac{f1}{f}.Math..$

[0354] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00106]$1\text{.2}<.Math.\frac{f2}{f}.Math.<1.64.$

[0355] The third lens G22 has positive focal power, and a ratio of a focal length f3 of the third lens G22 to the total focal length f of the camera lens is as follows:

[00107]$0.28<.Math.\frac{f3}{f}.Math.<0.38.$

[0356] The fourth lens G23 has negative focal power, and a ratio of a focal length f4 of the fourth lens G23 to the total focal length f of the camera lens is as follows:

[00108]$0.23<.Math.\frac{f4}{f}.Math.<0.31.$

[0357] The fifth lens G24 has negative focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length of the camera lens is as follows:

[00109]$0.44<.Math.\frac{f5}{f}.Math.<0.59.$

[0358] The sixth lens G25 has positive focal power, and a ratio of a focal length f6 of the sixth lens G25 to the total focal length f of the camera lens is as follows:

[00110]$0.56<.Math.\frac{f6}{f}.Math.<0.76.$

[0359] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00111]$1.01<\frac{TTL}{f}<1.074.$

[0360] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00112]$0.18<\frac{IMH}{f}<0.14.$

[0361] Table 13-1 shows optical parameters of the camera lens.

TABLE-US-00040 TABLE 13-1 Optical parameter System focal length (F) 12.14 mm < F < 16.18 mm Aperture number (F/#) 3.40 Image height (IMH) 2.25 mm Total track length (TTL) 13 mm < TTL < 16.4 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0362] Table 13-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00041 TABLE 13-2 R Thickness nd vd G0 R1 Infinity/ 0.3 n1 1.29 v1 108.49 (zoom 31.392/38.439 liquid R2 Infinity 0.1 n1 1.51 v1 64.16 lens) R3 Infinity 0.2 G1 R1 17.931 d1 0.5 n1 1.90 v1 37.05 R2 Infinity d2 0 A-01 Infinity d3 2.2 n2 1.90 v2 37.05 B-03 Infinity d4 2.2 C-02 Infinity d5 2.03 G21 R1 2.588 d6 1.3 n1 1.54 v1 55.86 R2 53.188 d7 0.25 G22 R1 4.916 d8 0.297 n1 1.65 v1 21.53 R2 4.969 d9 1.216 G23 R1 49.381 d10 1.198 n1 1.54 v1 55.86 R2 4.27 d11 0.209 G24 R1 11.773 d12 0.885 n1 1.65 v1 21.53 R2 3.837 d13 0.321 G25 R1 4.757 d14 1.421 n1 1.65 v1 21.53 R2 25.142 d15 1.187 G3 R1 Infinity d16 0.21 n1 1.51 v1 64.16 R2 Infinity d17 1.93

[0363] Table 11-3 shows aspheric coefficients of the lenses in Table 11-2.

TABLE-US-00042 TABLE 13-3 Norm Type K Rad a2 a3 a4 a5 G21 R1 EA 0.00 1.206 7.44E03 2.47E03 2.18E03 5.61E06 R2 EA 44.46 1.206 5.60E02 2.52E02 3.19E03 5.49E05 G22 R1 EA 50.00 1.206 3.97E03 5.05E02 2.13E02 2.46E03 R2 EA 6.64 1.206 3.03E02 5.96E03 5.04E02 1.87E02 G23 R1 EA 0.00 1.206 8.11E02 2.64E02 3.40E03 2.11E04 R2 EA 27.75 1.206 4.41E02 3.22E02 1.68E02 7.61E05 G24 R1 EA 0.00 1.206 6.45E02 2.96E02 4.05E03 9.68E04 R2 EA 12.05 1.206 1.98E01 8.04E02 9.67E03 1.03E04 G25 R1 EA 47.55 1.206 1.32E01 6.47E02 1.44E02 2.21E03 R2 EA 45.97 1.206 8.96E03 7.36E03 4.65E04 9.77E05

[0364] The camera lens includes a total of 10 extended aspheric surfaces.

[0365] In this embodiment, vector heights z of all extended aspheric surfaces may be defined by using the following formula, but are not limited to the following formula:

[00113]$Z=\frac{C{r}^2}{1+\sqrt{1-\left(K+1\right)C^2{r}^2}}+a_1{r}^2+a_2{r}^4+a_3{r}^6+a_4{r}^8+a_5{r}^{10}+.Math.,$

where [0366] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, C indicates vertex curvature of the aspheric surface, and a.sub.1, a.sub.2, a.sub.3, and the like are aspheric coefficients.

[0367] FIG. 32a shows curves of axial aberration in the structure of the camera lens shown in FIG. 31 based on the data shown in Table 13-1, Table 13-2, and Table 13-3. Five curves shown in FIG. 32a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively. It can be learned from FIG. 32a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0368] FIG. 32b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 31 based on the data shown in Table 13-1, Table 13-2, and Table 13-3. Five curves shown in FIG. 32b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 32b that lateral aberration of light with different wavelengths is within the diffraction range.

[0369] FIG. 32c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 31 based on the data shown in Table 13-1, Table 13-2, and Table 13-3. FIG. 32d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 32c and FIG. 32d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0370] FIG. 33 is a diagram of a structure of another camera lens. A lens group G2 includes five lenses. The five lenses are a second lens G21, a third lens G22, a fourth lens G23, a fifth lens G24, and a sixth lens G25 that are sequentially disposed along a second optical axis X2. An object-side surface of the second lens G21 is opposite to an image-side surface of a prism G12. In addition, the camera lens further includes an IR filter G3. An image-side surface of the sixth lens G25 is a convex surface.

[0371] A ratio of a focal length f1 of a refractive prism group G1 to a total focal length f of the camera lens is as follows:

[00114]$.Math.\frac{f1}{f}.Math.=0.533.$

[0372] The second lens G21 has negative focal power, and a ratio of a focal length f2 of the second lens G21 to the total focal length f of the camera lens is as follows:

[00115]$.Math.\frac{f2}{f}.Math.=17.926.$

[0373] The third lens G22 and the fourth lens G23 form a glued lens. The glued lens has negative focal power, and a ratio of a focal length f3 of the glued lens to the total focal length f of the camera lens is as follows:

[00116]$.Math.\frac{f3}{f}.Math.=0.467.$

[0374] The fifth lens G24 has negative focal power, and a ratio of a focal length f5 of the fifth lens G24 to the total focal length f of the camera lens is as follows:

[00117]$.Math.\frac{f5}{f}.Math.=0.433.$

[0375] The sixth lens G25 has positive focal power, and a ratio of a focal length f6 of the sixth lens G25 to the total focal length f of the camera lens is as follows:

[00118]$.Math.\frac{f6}{f}.Math.=0.32.$

[0376] In addition, a ratio of a total track length (total track length, TTL) of the camera lens to the total focal length f of the camera lens is as follows:

[00119]$\frac{TTL}{f}=0.965.$

[0377] A ratio of an image height of the camera lens to the total focal length f of the camera lens is as follows:

[00120]$\frac{IMH}{f}=0.088.$

[0378] Table 14-1 shows optical parameters of the camera lens.

TABLE-US-00043 TABLE 14-1 Optical parameter System focal length (F) 28.39 mm Aperture number (F/#) 3.81 Image height (IMH) 2.5 mm Total track length (TTL) 27.45 mm Designed wavelength 650 nm, 610 nm, 555 nm, 510 nm, and 470 nm

[0379] Table 14-2 shows optical parameters of optical components in the camera lens.

TABLE-US-00044 TABLE 14-2 Radius Thickness nd vd G1 R1 9.4 d1 1.2 n1 1.62 v1 63.85 R2 Infinity d2 0 n1 1.90 v1 37.05 A-01 Infinity d3 4 n2 1.90 v2 37.05 B-03 Infinity d4 4 C-02 Infinity d5 0.662 G21 R1 6.698 d6 1.088 n1 1.76 v1 49.64 R2 7.296 d7 0.075 G22 R1 158.042 d8 0.525 n1 1.60 v1 65.45 R2 Infinity d9 0.3 1.62 24.26 G23 R1binary2 8.38 d10 0.864 G24 R1 45.938 d11 0.6 n1 1.74 v1 27.76 R2 7.605 d12 0.987 G25 R1 9.099 d13 1.319 n1 1.90 v1 37.05 R2 80.00 d14 0.976 G3 R1 Infinity d15 0.193 n1 1.51 v1 64.16 R2 Infinity d16 15.345

[0380] Table 14-3 shows aspheric coefficients of the lenses in Table 14-2. An image-side surface and an object-side surface of the second lens G21 each are an even-order aspheric surface.

TABLE-US-00045 TABLE 14-3 Type K A2 A3 A4 A5 G21 R1 Even- 0.0 1.43E03 2.06E06 5.01E06 2.25E06 order aspheric surface R2 Even- 0.0 1.66E03 3.71E05 1.10E06 7.62E07 order aspheric surface Type K A6 A7 A8 R1 Even- 0.0 4.01E07 3.95E08 1.53E09 order aspheric surface R2 Even- 0.0 1.60E07 1.79E08 7.40E10 order aspheric surface

[0381] Table 14-4 shows a diffractive coefficient of the fourth lens G23.

TABLE-US-00046 TABLE 14-4 Binary 2 Diffraction Norm order radius (Diffract (Norm coeff. coeff. coeff. coeff. Order) Radius) on p{circumflex over ()}2 on p{circumflex over ()}4 on p{circumflex over ()}6 on p{circumflex over ()}8 G4 R1 1 2.533 1.50E+02 8.35E+01 4.24E+01 0.00E+00

[0382] It can be learned from Table 14-3 that the camera lens provided in this embodiment includes two aspheric surfaces. In this embodiment, vector heights z of all even-order aspheric surfaces may also be defined by using the following formula, but are not limited to the following formula:

[00121]$Z=\frac{C{X}^2}{1+\sqrt{1-K{C}^2{X}^2}}+A_2{r}^4+A_3{r}^6+A_4{r}^8+A_5{r}^{10}+A_6{r}^{12},$

where [0383] Z indicates a vector height of an aspheric surface, r indicates a radial coordinate of the aspheric surface, and C indicates vertex curvature of the aspheric surface.

[0384] In this embodiment, a vector height Z2 of the binary 2 diffractive surface may be defined by using the following formula:

[00122]$Z2=\frac{C{r}^2}{1+\sqrt{1-K{C}^2{r}^2}}+\underset{i=1}{\overset{8}{.Math.}}{a}_i{r}^{2i}+M\underset{J=1}{\overset{N}{.Math.}}{A}_j{p}^{2j},$

where [0385] M indicates a diffraction order, P indicates a phase distribution power, A indicates a phase distribution coefficient, C indicates vertex curvature of an aspheric surface, and r indicates a radial coordinate of the aspheric surface.

[0386] FIG. 34a shows curves of axial aberration in the structure of the camera lens shown in FIG. 33 based on the data shown in Table 14-1, Table 14-2, Table 14-3, and Table 14-4. Five curves shown in FIG. 34a are curves of axial aberration corresponding to designed wavelengths of 650 nm, 634 nm, 555 nm, 534 nm, and 470 nm respectively. It can be learned from FIG. 34a that axial aberration of light with different wavelengths is controlled within a quite small range.

[0387] FIG. 34b shows curves of lateral aberration in the structure of the camera lens shown in FIG. 33 based on the data shown in Table 14-1, Table 14-2, Table 14-3, and Table 14-4. Five curves shown in FIG. 34b are curves of lateral aberration corresponding to designed wavelengths of 650 nm, 634 nm, 555 nm, 534 nm, and 470 nm respectively, and a dashed line indicates a diffraction limit range. It can be learned from FIG. 34b that lateral aberration of light with different wavelengths is within the diffraction range.

[0388] FIG. 34c shows curves of distortion aberration in the structure of the camera lens shown in FIG. 33 based on the data shown in Table 14-1, Table 14-2, Table 14-3, and Table 14-4. FIG. 34d shows a curve of ideal distortion aberration. It can be learned through comparison between FIG. 34c and FIG. 34d that distortion aberration of light with different wavelengths is within a range recognizable to naked eyes.

[0389] In the descriptions of this specification, specific features, structures, materials, or characteristics may be combined in a proper manner in any one or more of embodiments or examples.

[0390] 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.