TW202307499A - Camera module, imaging module and electronic device - Google Patents

Abstract

A camera module includes an imaging lens assembly and an image sensor. The imaging lens assembly includes a plastic optical element. A light blocking layer is disposed on a transparent surface of the plastic optical element, the plastic optical element includes an optical effective area, a specific shape is formed around the optical effective area via a peripheral area of the light blocking layer so that a clear area is defined via the light blocking layer, and the clear area is corresponding to the optical effective area. The peripheral area includes a main portion and a compensation portion. The compensation portion is disposed on an edge of the main portion adjacent to the optical effective area, the compensation portion is closer to the optical effective area than the main portion to the optical effective area, the compensation portion extends towards a direction close to the optical effective area, and the optical density of the compensation portion is lower than the optical density of the main portion. The image sensor is disposed on an image side of the imaging lens assembly. Therefore, it is favorable for enhancing the optical quality.

Description

Camera module, image module and electronic device

The disclosure relates to a camera module and an image module, and in particular to a camera module and an image module applied to a portable electronic device.

In recent years, portable electronic devices have developed rapidly, such as smart electronic devices, tablet computers, etc., which have flooded the lives of modern people, and the camera modules and video modules loaded on portable electronic devices have also followed suit. Flourish. Due to the advancement of semiconductor technology, the light sensitivity and resolution of image sensors have been greatly improved, making the flaws of the light-shielding film in the imaging lens an issue that cannot be ignored.

The light-shielding film layer in the prior art often achieves the light-shielding effect through excessive light-shielding, so that the surrounding optical quality is sacrificed and the relative illuminance is reduced, and the light-shielding film layer in the prior art cannot form a specific shape at the micron scale.

Furthermore, if there is a defect in the edge area of the light-shielding film layer, the unexpected light that was originally shielded will pass through, resulting in a decrease in optical quality, and the cause of the defect may be a random defect generated during molding, or it may be the The inability to achieve micron-scale size control results in. On the other hand, the uniformity of the film thickness will determine the shading quality. The thinner part of the shading film may be penetrated by light, and the noise formed by the penetrating light on the image sensor will be difficult to eliminate. Due to the advancement of electronic technology, the photosensitive element can obtain light information with lower brightness, so that it can work in a dark environment, but when the optical density of the light-shielding film layer is insufficient, the light will penetrate the light-shielding film layer and be received by the photosensitive element form noise.

Please refer to FIG. 8A to FIG. 8F , wherein FIG. 8A to FIG. 8F are diagrams illustrating a light-shielding film layer 860 according to the prior art. From Figures 8A to 8F, it can be seen that the light-shielding film layer 860 is often used to control the light path of light, thereby eliminating spots or glare. However, when the incident light is too strong, the edge of the light-shielding film layer 860 is easy to Stray light is generated and affects the optical quality, which is caused by defects P, P1, P2, P2', and P3 in the light-shielding film layer. The defects P, P1, P2, P2', and P3 can be divided into three points for discussion. One is that there are defects in the edge area of the light-shielding film layer 860 , the second is that the coating of the light-shielding film layer 860 is uneven, and the third is that the optical density of the light-shielding film layer 860 is insufficient. Specifically, the defects P and P1 exist in the edge area (not shown in the figure) of the light-shielding film layer 860, that is, the main body 862 of the edge area. reasons are limited. It must be noted that the main body portion 862 is in physical contact with the light-transmitting surface 871 of the plastic optical element (not shown). The defect P2 is caused by the uneven optical density of the light-shielding film layer 860. The reason for the formation of the defect P2 may be that the light-shielding film layer 860 is gathered at the edge due to the influence of surface tension, or it may be that the light-shielding film layer 860 is caused by protrusions or The reasons for the depression and aggregation are not limited to the above, and the defect P2 may further cause insufficient optical density of the surrounding light-shielding film layer 860 to form the defect P2'. The defect P3 is caused by insufficient optical density of the light-shielding film layer 860 , which may be caused by a height drop on the surface, and is not limited to the above reasons.

Therefore, developing a camera module and image module with a light-shielding film layer with precisely controlled properties has become an important and urgent problem in the industry.

The present disclosure provides a camera module, an image module, and an electronic device, which improve the optical quality by arranging a light-shielding film layer with precise control characteristics on a plastic optical element.

According to an embodiment of the disclosure, a camera module is provided, which includes an imaging lens and an image sensor. The imaging lens includes a plastic optical element. A light-shielding film layer is disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, and an edge area of the light-shielding film layer forms a specific shape around the optically effective area, so that the light-shielding film layer is used to define a pass through The light area and the light-through area correspond to the optical effective area, wherein the edge area includes a main part and a compensation part. The main body is in physical contact with the transparent surface. The compensation part is arranged on the edge of the main body adjacent to the optical effective area, the compensation part is closer to the optical effective area than the main body, the compensation part extends toward the direction closer to the optical effective area, and the compensation part has a lower optical density than the main body. The image sensor is disposed on the image side of the imaging lens, the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height to define a relative illuminance. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped mark structure, the ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area. The relative illuminance of the imaging lens is RI, the optical density of the main part is DM, the thickness of the main part is T, and the extension distance of the compensation part is L, which meets the following conditions: -LOG(RI)/DM ≤ 1.2; 3 degrees ≤ tan ^-1 (T/L) ≤ 89.5 degrees; 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 ; and 0 um < L ≤ 32 um.

According to the camera module described in the preceding paragraph, the maximum image height of the imaging lens is used to define a half angle of view, the half angle of view is HFOV, and the relative illuminance of the imaging lens is RI, which can satisfy the following conditions: 0.04 ≤ RI×sin(HFOV ) ≤ 0.35.

In the camera module according to the embodiment described in the preceding paragraph, wherein the thickness of the main body is T, which can satisfy the following conditions: 0.14 um ≤ T ≤ 9.85 um. In addition, it can satisfy the following condition: 0.28 um ≤ T ≤ 4.95 um. In addition, it may satisfy the following condition: 0.48 um ≤ T ≤ 1.95 um.

According to the camera module described in the preceding paragraph, the extension distance of the compensation part is L, which can satisfy the following condition: 0 um < L ≤ 16 um. In addition, it can satisfy the following condition: 0 um < L ≤ 7 um.

According to the camera module described in the preceding paragraph, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions can be met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

According to the camera module described in the preceding paragraph, the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic lens, the plastic lens includes an aspheric surface, and the aspherical surface corresponds to the optical effective area.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the reflective surface and the optical effective area are arranged on the same optical path.

An embodiment according to the present disclosure provides an electronic device, including at least one camera module as in the foregoing embodiments.

According to an embodiment of the disclosure, a camera module is provided, which includes an imaging lens and an image sensor. The imaging lens includes a plastic optical element. A light-shielding film layer is disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, and an edge area of the light-shielding film layer forms a specific shape around the optically effective area, so that the light-shielding film layer is used to define a pass through The light area and the light-through area correspond to the optical effective area, wherein the edge area includes a main part and a compensation part. The main body is in physical contact with the transparent surface. The compensation part is arranged on the edge of the main body adjacent to the optical effective area, the compensation part is closer to the optical effective area than the main body, the compensation part extends toward the direction closer to the optical effective area, and the compensation part has a lower optical density than the main body. The image sensor is disposed on the image side of the imaging lens, the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height to define a relative illuminance. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped mark structure, the ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area. The relative illuminance of the imaging lens is RI, the optical density of the main body is DM, a thickness of the main body is T, a maximum extension distance of the compensation part is Lmax, and an area of the compensation part is A, which satisfies the following conditions: -LOG( RI)/DM ≤ 1.2; 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 ; 0 um < Lmax ≤ 32 um; and 0 < Lmax/√(A) ≤ 0.98.

According to the camera module described in the preceding paragraph, the maximum image height of the imaging lens is used to define a half angle of view, the half angle of view is HFOV, and the relative illuminance of the imaging lens is RI, which can satisfy the following conditions: 0.04 ≤ RI×sin(HFOV ) ≤ 0.35.

According to the camera module described in the preceding paragraph, wherein the thickness of the main body is T, and the maximum extension distance of the compensation part is Lmax, which can satisfy the following conditions: 3 degrees ≤ tan ^-1 (T/Lmax) ≤ 89.5 degrees.

According to the camera module described in the preceding paragraph, the maximum extension distance of the compensation part is Lmax, which can satisfy the following condition: 0 um < Lmax ≤ 16 um. In addition, it can satisfy the following condition: 0 um < Lmax ≤ 7 um.

In the camera module according to the embodiment described in the preceding paragraph, wherein the thickness of the main body is T, which can satisfy the following conditions: 0.14 um ≤ T ≤ 9.85 um. In addition, it can satisfy the following condition: 0.28 um ≤ T ≤ 4.95 um. In addition, it may satisfy the following condition: 0.48 um ≤ T ≤ 1.95 um.

According to the camera module described in the preceding paragraph, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions can be met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

According to the camera module described in the preceding paragraph, the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic lens, the plastic lens includes an aspheric surface, and the aspherical surface corresponds to the optical effective area.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the reflective surface and the optical effective area are arranged on the same optical path.

An embodiment according to the present disclosure provides an electronic device, including at least one camera module as in the foregoing embodiments.

According to an embodiment of the disclosure, a camera module is provided, which includes an imaging lens and an image sensor. The imaging lens includes a plastic optical element. A light-shielding film layer is disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, and an edge area of the light-shielding film layer forms a specific shape around the optically effective area, so that the light-shielding film layer is used to define a pass through The light area and the light-through area correspond to the optical effective area, wherein the edge area includes a main part and a compensation part. The main body is in physical contact with the transparent surface. The compensation part is arranged on the edge of the main body adjacent to the optical effective area, the compensation part is closer to the optical effective area than the main body, the compensation part extends toward the direction closer to the optical effective area, and the compensation part has a lower optical density than the main body. The compensation part includes a tip and a reverse slope. The tip is disposed at the end away from the main body. The reverse slope faces the light-transmitting surface, the reverse slope approaches the light-transmitting surface from the tip to the main body, and an air interlayer is formed between the reverse slope and the light-transmitting surface. The image sensor is disposed on the image side of the imaging lens, the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height to define a relative illuminance. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped mark structure, the ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area. The relative illuminance of the imaging lens is RI, the optical density of the main part is DM, the thickness of the main part is T, and the extension distance of the compensation part is L, which meets the following conditions: -LOG(RI)/DM ≤ 1.2; 3 degrees ≤ tan ^-1 (T/L) ≤ 89.5 degrees; and 0 um < L ≤ 32 um.

According to the camera module described in the preceding paragraph, the maximum image height of the imaging lens is used to define a half angle of view, the half angle of view is HFOV, and the relative illuminance of the imaging lens is RI, which can satisfy the following conditions: 0.04 ≤ RI×sin(HFOV ) ≤ 0.35.

According to the camera module described in the preceding paragraph, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions can be satisfied: 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 . In addition, it may satisfy the following condition: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

According to the camera module described in the preceding paragraph, the extension distance of the compensation part is L, which can satisfy the following condition: 0 um < L ≤ 16 um. In addition, it can satisfy the following condition: 0 um < L ≤ 7 um.

In the camera module according to the embodiment described in the preceding paragraph, wherein the thickness of the main body is T, which can satisfy the following conditions: 0.14 um ≤ T ≤ 9.85 um. In addition, it can satisfy the following condition: 0.28 um ≤ T ≤ 4.95 um. In addition, it may satisfy the following condition: 0.48 um ≤ T ≤ 1.95 um.

According to the camera module described in the preceding paragraph, the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic lens, the plastic lens includes an aspheric surface, and the aspherical surface corresponds to the optical effective area.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the reflective surface and the optical effective area are arranged on the same optical path.

An embodiment according to the present disclosure provides an electronic device, including at least one camera module as in the foregoing embodiments.

According to an embodiment of the disclosure, a camera module is provided, which includes an imaging lens and an image sensor. The imaging lens includes a plastic optical element. A light-shielding film layer is disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, and an edge area of the light-shielding film layer forms a specific shape around the optically effective area, so that the light-shielding film layer is used to define a pass through The light area corresponds to the optical effective area, and the edge area includes a main body. The main body is formed into a specific shape. The image sensor is disposed on the image side of the imaging lens, the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height to define a relative illuminance and a half viewing angle. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped mark structure, the ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area. The thickness of the main body is T, the optical density of the main body is DM, the relative illuminance of the imaging lens is RI, and the half angle of view is HFOV, which satisfy the following conditions: -LOG(RI)/DM ≤ 1.2; 0.14 um ≤ T ≤ 9.85 um; 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 ; and 0.04 ≤ RI×sin(HFOV) ≤ 0.35.

According to the camera module described in the preceding paragraph, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions can be met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

According to the camera module described in the preceding paragraph, the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic lens, the plastic lens includes an aspheric surface, and the aspherical surface corresponds to the optical effective area.

According to the camera module described in the preceding paragraph, the plastic optical element can be a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the reflective surface and the optical effective area are arranged on the same optical path.

An embodiment according to the present disclosure provides an electronic device, including at least one camera module as in the foregoing embodiments.

According to an embodiment of the present disclosure, an image module is provided, which includes a lens and an image source, wherein the lens includes a glass lens and a plastic lens, and the image source is disposed on the light-incident side of the lens. Glass lenses are closer to the image source than plastic lenses. A light-shielding film layer is arranged on a light-transmitting surface of the plastic lens, and the plastic lens includes an optical effective area. An edge area of the light-shielding film layer forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-passing area, and the light-passing area corresponds to the optically effective area. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped mark structure, the ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area. The edge area includes a main body, wherein the main body forms a specific shape. A thickness of the main body is T, an optical density of the main body is DM, which satisfy the following conditions: 0.14 um ≤ T ≤ 9.85 um; and 0.7 um ⁻¹ ≤ DM/T ≤ 7.2 um ⁻¹ .

According to the image module described in the preceding paragraph, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions can be met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

According to the image module described in the preceding paragraph, the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following condition: 0 ≤ |1-RO/RM| ≤ 0.6.

In the image module according to the embodiment described in the preceding paragraph, the optically effective area of the light-transmitting surface can be an aspheric surface, and the aspheric surface includes at least one inflection point.

An embodiment according to the present disclosure provides an electronic device, which includes at least one image module as in the foregoing embodiment.

According to an embodiment of the present disclosure, an image module is provided, which includes a lens and an image source, wherein the lens includes a reflective element and a plastic lens in sequence from the light incident side to the light output side, and the image source is arranged on the light incident side of the lens. side. A light-shielding film layer is arranged on a light-transmitting surface of the plastic lens, and the plastic lens includes an optical effective area. An edge area of the light-shielding film layer forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-passing area, and the light-passing area corresponds to the optically effective area. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped mark structure, the ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area. The edge area includes a main body, wherein the main body forms a specific shape. A thickness of the main body is T, an optical density of the main body is DM, which satisfy the following conditions: 0.14 um ≤ T ≤ 9.85 um; and 0.7 um ⁻¹ ≤ DM/T ≤ 7.2 um ⁻¹ .

According to the image module described in the preceding paragraph, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions can be met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

According to the image module described in the preceding paragraph, the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following condition: 0 ≤ |1-RO/RM| ≤ 0.6.

In the image module according to the embodiment described in the preceding paragraph, the optically effective area of the light-transmitting surface can be an aspheric surface, and the aspheric surface includes at least one inflection point.

An embodiment according to the present disclosure provides an electronic device, which includes at least one image module as in the foregoing embodiment.

The disclosure provides a camera module including an imaging lens and an image sensor. The imaging lens includes a plastic optical element, wherein a light-shielding film layer is arranged on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optical effective area. Furthermore, an edge area of the light-shielding film layer forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-passing area, and the light-passing area corresponds to the optically effective area. The edge area includes a main body, wherein the main body can be in physical contact with the light-transmitting surface, and the main body can be formed into a specific shape. The image sensor is disposed on the image side of the imaging lens, the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height to define a relative illuminance. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped marking structure, and the ring-shaped marking structure has an angle end, and the angle end surrounds the optical effective area. The relative illuminance of the imaging lens is RI, and the optical density of the main body is DM, which satisfies the following conditions: -LOG(RI)/DM ≤ 1.2. When -LOG(RI)/DM ≤ 1.2 is satisfied, the light-shielding film layer has sufficient optical density for the imaging lens.

In detail, the angle end of the ring-shaped marking structure can be integrally formed to surround the optical effective area, and the ring-shaped marking structure can be used as an alignment mark when covering the light-shielding film layer, and can also be used as a tool for detecting the offset of the optical effective area. Datums or alignment marks for assembly, but not limited to. Thereby, the overall optical quality of the imaging lens can be improved. In addition, the ring-shaped marking structure can further correspond to the demoulding direction of the plastic injection molding mold, so that the ring-shaped marking structure is integrally formed on the plastic optical element, so as to ensure the relative position of the ring-shaped marking structure and other components.

Relative illuminance is used to describe the intensity ratio of peripheral rays to central rays when light passes through the imaging lens and converges on the imaging surface. The value is between 0 and 1. In detail, the intensity ratio of peripheral rays to central rays can be greater than 0.1. It can further be greater than 0.2. Specifically, the relative illuminance corresponds to the maximum image height of the image sensor. When the image sensor is rectangular, the maximum image height can be defined as half of the diagonal length of the image sensor; when the image sensor When the sensor is non-rectangular, the maximum image height can be defined as the radius of the smallest circumscribed circle of the image sensor.

Optical density refers to the intensity of shielding against visible light (the common visible light range can be defined as 400 nm to 700 nm, or 380 nm to 720 nm, but not limited thereto). The light-shielding film layer can provide an optical density ranging from greater than or equal to 1.0 to less than or equal to 9.0, but not limited thereto.

The specific shape means that the edge region of the light-shielding film layer forms an unexpected shape at the micron scale, and the specific shape is controllable at the micron scale.

The edge area may further include a compensating portion, wherein the compensating portion is disposed on the edge of the main body adjacent to the optical effective area. The compensation part is closer to the optical effective area than the main body, the compensation part extends toward the direction closer to the optical effective area, and the compensation part has a lower optical density than the main body. Specifically, the compensation part has pre-compensation functionality, which can eliminate random defects that may occur in the main body part, and can achieve better roundness in the edge area, so as to ensure the light-shielding function of the light-shielding film layer.

The compensation portion may include a tip and a reverse slope, wherein the point is disposed at an end away from the main body, and the reverse slope faces the light-transmitting surface. The reverse slope approaches the light-transmitting surface from the tip to the main body, and an air interlayer is formed between the reverse slope and the light-transmitting surface. In this way, a light trap structure is formed between the compensation part and the plastic optical element to reduce the generation of stray light.

The plastic optical element can be a plastic lens, wherein the plastic lens includes an aspheric surface, and the aspheric surface corresponds to the optical effective area. Alternatively, the plastic optical element can be a plastic reflective element, wherein the plastic reflective element includes at least one reflective surface, and the reflective surface and the optical effective area are arranged on the same optical path.

A thickness of the main body is T, and an extension distance of the compensation part is L, which can satisfy the following conditions: 3 degrees ≤ tan ^-1 (T/L) ≤ 89.5 degrees. When 3 degrees ≤ tan ^-1 (T/L) ≤ 89.5 degrees, the size of the compensation part can be well controlled, thereby improving the yield.

The optical density of the main body is DM, and the thickness of the main body is T, which can satisfy the following conditions: 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 . When 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 is satisfied, the thickness of the light-shielding film layer can be reduced while the main body has sufficient light-shielding functionality, and the uniformity of thickness can be improved. In addition, it may satisfy the following condition: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

The extension distance of the compensation part is L, which can satisfy the following conditions: 0 um < L ≤ 32 um. When 0 um < L ≤ 32 um is satisfied, the formability of the compensation part can be ensured and pollution caused by peeling can be avoided. In addition, it can meet the following conditions: 0 um < L ≤ 16 um. Furthermore, it can satisfy the following condition: 0 um < L ≤ 7 um.

A maximum extension distance of the compensation part is Lmax, which can satisfy the following condition: 0 um < Lmax ≤ 32 um. When 0 um < Lmax ≤ 32 um is satisfied, the formability of the compensation part can be further ensured. In addition, it can satisfy the following condition: 0 um < Lmax ≤ 16 um. Furthermore, it can satisfy the following condition: 0 um < Lmax ≤ 7 um.

A maximum extension distance of the compensation part is Lmax, and an area of the compensation part is A, which can satisfy the following conditions: 0 < Lmax/√(A) ≤ 0.98. When 0 < Lmax/√(A) ≤ 0.98 is satisfied, the formability of the compensation part can be ensured and pollution caused by peeling can be avoided. In addition, it may satisfy the following condition: 0.05 ≤ Lmax/√(A) ≤ 0.9. Furthermore, it may satisfy the following condition: 0.1 ≤ Lmax/√(A) ≤ 0.8.

The maximum image height of the imaging lens is used to define the half angle of view, the half angle of view is HFOV, and the relative illuminance of the imaging lens is RI, which can meet the following conditions: 0.04 ≤ RI×sin(HFOV) ≤ 0.35. When 0.04 ≤ RI×sin(HFOV) ≤ 0.35 is satisfied, the precision of the light-shielding film layer has a significant impact on the optical quality. In addition, it may satisfy the following condition: 0.05 ≤ RI×sin(HFOV) ≤ 0.3. Furthermore, it may satisfy the following condition: 0.1 ≤ RI×sin(HFOV) ≤ 0.2.

The thickness of the main body is T, which can satisfy the following conditions: 0.14 um ≤ T ≤ 9.85 um. A sufficiently thin thickness can prevent the accumulation of the light-shielding film layer during molding, so as to improve the uniformity of the thickness of the light-shielding film layer. In addition, it can satisfy the following condition: 0.28 um ≤ T ≤ 4.95 um. Furthermore, it can satisfy the following condition: 0.48 um ≤ T ≤ 1.95 um.

The roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6. When 0 ≤ |1-RO/RM| ≤ 0.6 is satisfied, the thickness uniformity can be further controlled. It must be noted that in this disclosure, the roughness RO of the light-transmitting surface and the roughness RM of the main body are both measured by Ra as a statistical method.

The thickness of the main part is T, and the maximum extension distance of the compensation part is Lmax, which can satisfy the following conditions: 3 degrees ≤ tan ^-1 (T/Lmax) ≤ 89.5 degrees. When 3 degrees ≤ tan ^-1 (T/Lmax) ≤ 89.5 degrees is satisfied, the light-shielding function of the light-shielding film layer can be further ensured.

All the technical features in the above-mentioned camera module disclosed in this disclosure can be combined and configured to achieve corresponding effects.

The disclosure provides an electronic device including at least one aforementioned camera module.

The disclosure provides an image module, which includes a lens and an image source, wherein the lens includes a plastic lens, and the image source is disposed on the light-incident side of the lens. A light-shielding film layer is arranged on a light-transmitting surface of the plastic lens, and the plastic lens includes an optical effective area. An edge area of the light-shielding film layer forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-passing area, and the light-passing area corresponds to the optically effective area. The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um. The light-transmitting surface includes a ring-shaped mark structure, the ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area. The edge area includes a main body forming a specific shape. A thickness of the main body is T, an optical density of the main body is DM, which satisfy the following conditions: 0.14 um ≤ T ≤ 9.85 um; and 0.7 um ⁻¹ ≤ DM/T ≤ 7.2 um ⁻¹ .

Specifically, the image module can be a single set of lenses or multiple sets of lenses, and the light from the image source entering the lens can be converged or diverged.

The image source can be a liquid crystal display (LCD), digital light processing (DLP), laser light source, ultraviolet light source or infrared light source, and the image source can further include optical elements such as a lens array, dodging sheet, glass slide, and an image transmission A module, wherein the image transmission module can be a waveguide or an optical path turning mirror group, but it is not limited thereto.

The lens may further include a glass lens, wherein the glass lens is closer to the image source than the plastic lens. Thereby, the influence of waste heat of the image source on the optical properties of the plastic lens can be reduced to ensure the optical quality of the lens.

The lens may further include a reflection element. Specifically, the lens includes a reflection element and a plastic lens sequentially from the light incident side to the light output side. The overall height of the image module can be reduced through the reflective element, thereby facilitating miniaturization, and can be applied to head-mounted devices, but is not limited thereto.

The optically effective area of the light-transmitting surface can be an aspheric surface, wherein the aspheric surface includes at least one inflection point.

The optical density of the main body is DM, and the thickness of the main body is T, which can satisfy the following conditions: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 .

The roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which can satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6.

All the technical features in the image module of the above disclosure can be combined and configured to achieve corresponding effects.

The present disclosure provides an electronic device including at least one aforementioned image module.

Overall, the camera module and image module according to the present disclosure can improve the thickness uniformity of the light-shielding film layer, and make the light-transmitting surface in physical contact with the light-shielding film layer have low surface roughness, and can avoid the light-shielding film layer The uneven thickness at the micron scale reduces the risk of light penetrating through the thinner parts of the light-shielding film. Furthermore, the surface of the light-shielding film layer may also have a low surface roughness, thereby further ensuring the thickness uniformity of the light-shielding film layer. Moreover, the thinner light-shielding film layer can overcome the situation of light-shielding film layer aggregation, and further improve the thickness uniformity of the light-shielding film layer.

Furthermore, the light-shielding film layer has excellent optical density. Further, when the optical density of the main body is O.D. and the thickness of the main body is T, it satisfies the following conditions: 1.0 ≤ O.D. ≤ 9; and 0.14 um ≤ T ≤ 9.85 um. Under the above conditions, the intensity of light passing through the shading film is I(out), and the intensity of light entering the shading film is I(in), where O.D. is defined as -log(I(out)/I(in)).

Specifically, the measuring method of the optical density is as follows.

Firstly, a plastic optical element with a light-shielding film layer is embedded in a transparent plastic to form a quasi-test object.

Second, plan a light-incident surface and a light-exit surface on the quasi-tested part, so that the light beam can pass through the light-incidence surface, light-shielding film layer and light-exit surface in sequence, and the necessary cutting can be performed on the light-incidence surface and the light-exit surface , grinding and polishing to form a test piece. In general, the light-incident surface is parallel to the light-exit surface, and the roughness is less than 0.5 um. It must be noted that the above-mentioned roughness uses Ra as the measurement and statistics method. If conditions permit, the shading film layer can be exposed on the light-incident surface. At this time, the light beam passes through the light-incident surface and the light-shielding film layer at the same time, and then passes through the light-emitting surface. The above-mentioned allowed conditions are flat and sufficiently large light-shielding film layer.

Third, prepare a control piece, which is molded from the above-mentioned transparent plastic, has a configuration and surface morphology similar to that of the test piece, but does not embed optical elements.

Fourth, the control piece is set between a light-emitting end and a receiving end, and the control piece is scanned in the visible light range (ie, 400 nm to 700 nm), and the scanning interval can be 1 nm, 5 nm, 10 nm or 0.5 nm, 0.1 nm, but not limited thereto. The light beam comes from the light-emitting end and passes through the light-incident surface and the light-emitting surface in sequence, and then is received by the receiving end to obtain intensity information, and the intensity information is averaged to obtain I(in).

Fifth, the DUT is set between the light-emitting end and the receiving end, and the DUT is scanned in the visible light range (ie, 400 nm to 700 nm). The scanning interval can be 1 nm, 5 nm, 10 nm or 0.5 nm, 0.1 nm, but not limited to this. The light beam from the light-emitting end passes through the light-incident surface, the light-shielding film layer, and the light-emitting surface in sequence, and then is received by the receiving end to obtain intensity information, and the intensity information is averaged to obtain I(out).

Sixth, perform mathematical operations on I(in) and I(out) to obtain the value of the optical density.

According to the above-mentioned features, the light-shielding film layer of the present disclosure has the characteristics of precise control compared with the prior art, and the precise control can be used to describe the light-shielding range, film thickness, film layer uniformity and other dimensions of the light-shielding film layer at the micron scale. controllable.

Please refer to Table 1, which is the experimental data of the lens covered with a light-shielding film layer in this disclosure, wherein the number of plastic lenses of the lens is N, the maximum image height of the lens is ImgH, the relative illuminance of the lens is RI, and the half of the lens is Viewing angle is HFOV. It must be noted that at least one of the N plastic lenses is coated with a light-shielding film layer, and serial numbers 1 to 35 and 37 to 39 are examples in the present disclosure, and serial number 36 is a comparative example. It can be seen from Table 1 that, except for No. 36, the stray light performance of the other numbers is sensitive to the dimensional accuracy of the light-shielding film layer and shows excellent relative illuminance and half viewing angle. It must be noted that No. 36 has no significant impact on the control of stray light. The reason is that No. 36 has a larger relative illuminance than other lenses (such as No. 04 and No. 05) with a half angle of view greater than 60 degrees, so that No. 36 In the case of excessive shading of the shading film, the negative impact on the relative illuminance of the lens is lower than that of other serial numbers. Table I serial number N ImgH (mm) RI (%) HFOV (degrees) RI×sin(HFOV) (%) 01 7 6.00 19.1 42.65 12.94 02 7 4.615 24.8 37.75 15.18 03 7 4.636 27.7 40.5 17.99 04 6 2.52 12.9 62.5 11.44 05 5 2.52 14.0 62.45 12.41 06 7 5.12 24.1 42.5 16.28 07 7 3.131 24.1 65.75 21.97 08 6 2.87 33.2 65.85 30.29 09 8 7.15 22.1 42.5 14.93 10 9 4.00 64.6 16.15 17.97 11 9 4.00 83.9 12.3 17.87 12 9 4.00 90.6 9.85 15.50 13 9 8.166 20.0 42.5 13.51 14 8 8.166 17.3 46 12.44 15 8 8.166 twenty one 42.65 14.23 16 8 7.145 24.7 42.5 16.69 17 7 5.12 13.8 59.9 11.94 18 7 6.53 22.9 42.75 15.54 19 7 4.626 17.5 52.45 13.87 20 7 6.00 26 40.6 16.92 twenty one 6 4.8 23.5 41.75 15.65 twenty two 7 4.00 16.4 61.1 14.36 twenty three 6 4.8 27.9 40.25 18.03 twenty four 7 5.161 22.8 41.5 15.11 25 7 5.161 23.3 41.55 15.45 26 6 3.24 26.8 80.1 26.40 27 5 3.269 38.3 24.4 15.82 28 5 3.269 38.2 24.3 15.72 29 5 2.87 20.6 44.25 14.37 30 5 2.911 30.2 36.85 18.11 31 5 2.502 61 9.75 10.33 32 7 6.1488 23.3 41.525 15.45 33 7 4.788 24.5 39.5 15.58 34 7 3.528 25.8 39.35 16.36 35 5 2.52 28.8 42.39 19.42 36 5 1.92 61.7 62.4 54.7 37 6 2.52 59.6 22.43 22.74 38 6 2.52 66.3 18.38 20.91 39 3 2.502 98.1 5.05 8.64

According to the above-mentioned implementation manners, specific implementation manners are proposed below and described in detail in conjunction with the drawings.

<First Embodiment>

Please refer to FIG. 1A to FIG. 1C, wherein FIG. 1A shows a schematic diagram of the camera module 10 according to the first embodiment of the disclosure, and FIG. 1B shows the imaging lens 110 according to the first embodiment of FIG. 1A. As a perspective view, FIG. 1C shows an exploded view of the imaging lens 110 in the first embodiment according to FIG. 1B . 1A to 1C, the camera module 10 includes an imaging lens 110, a carrier element 130, a filter element 140 and an image sensor 150, wherein an optical axis X passes through the imaging lens 110, and the image The sensor 150 is disposed on the image side of the imaging lens 110 .

The imaging lens 110 includes a plastic lens 111, a spacer element 121, a plastic lens 112, a spacer element 122, a plastic lens 113, a spacer element 123, a plastic lens 114, a spacer element 124, a plastic lens 115, and a spacer element from the object side to the image side. 125 , plastic lens 116 , fixing element 126 , wherein the plastic lenses 111 , 112 , 113 , 114 , 115 , 116 , spacer elements 121 , 122 , 123 , 124 , 125 , and fixing element 126 are disposed in the carrier element 130 . It must be noted that the number, structure, surface shape and other optical characteristics of the plastic lens and each optical element can be configured according to different imaging requirements, and it is not limited thereto.

Please refer to FIG. 1D and FIG. 1E , wherein FIG. 1D shows a schematic diagram of the plastic lens 111 according to the first embodiment shown in FIG. 1C , and FIG. 1E shows the light-shielding film layer 160 according to the first embodiment shown in FIG. 1D schematic diagram. From Figures 1B to 1E, it can be seen that the light-shielding film layer 160 is disposed on a light-transmitting surface 171 of the plastic lens 111, and the plastic lens 111 includes an optically effective area 172 and an injection mark 175, wherein an edge of the light-shielding film layer 160 The area 161 forms a specific shape around the optical effective area 172, so that the light-shielding film layer 160 is used to define a light-passing area, and the light-passing area corresponds to the optical effective area 172, and the injection marks 175 are arranged on the outer periphery of the plastic lens 111 (not shown in the figure). ). It must be noted that, in order to clearly show the position and range of the light-shielding film layer 160 , the thickness of the light-shielding film layer 160 in FIG. 1D is not the actual thickness.

Moreover, the light-transmitting surface 171 includes a ring-shaped marking structure 173 , wherein the ring-shaped marking structure 173 has an angled end 174 , and the angled end 174 surrounds the optically active area 172 . The plastic lens 111 includes an aspheric surface, and the aspherical surface corresponds to the optical effective area 172 . In detail, the ring-shaped marking structure 173 can surround the optical effective area 172 integrally, and the ring-shaped marking structure 173 can be used as an alignment mark and boundary when covering the light-shielding film layer 160, and can also be used as a detection optical effective area 172 Datum of offset or alignment mark for assembly, but not limited to. Thereby, the overall optical quality of the imaging lens 110 can be improved.

Please refer to FIG. 1F to FIG. 1H, wherein FIG. 1F shows a schematic diagram of the light-shielding film layer 160 according to the first embodiment shown in FIG. 1E, and FIG. 1G and FIG. 1H show the first embodiment according to FIG. 1E. A schematic diagram of the compensation portion 163 of the light-shielding film layer 160 . It can be seen from FIG. 1F to FIG. 1H that the edge region 161 includes a main body 162 and a compensation part 163, wherein the main body 162 is in physical contact with the light-transmitting surface 171, the main body 162 forms a specific shape, and the compensation part 163 is disposed on the main body Portion 162 adjoins the edge of optically active area 172 .

Specifically, the compensation unit 163 in FIG. 1G can improve the defect P in the prior art as in FIG. 8C , and the compensation unit 163 in FIG. 1H can improve the defect P in the prior art as in FIG. 8D . In this way, the compensating part 163 has pre-compensation functionality, which can eliminate random defects that may occur in the main body part 162 and achieve better roundness of the edge region 161 , so as to ensure the light-shielding function of the light-shielding film layer 160 .

The extension distance of the compensation part 163 is L, the maximum extension distance of the compensation part 163 is Lmax, and the area of the compensation part 163 is A, wherein Lmax/√(A) in FIG. 1G is 0.7.

Please refer to FIG. 1I to FIG. 1N, wherein FIG. 1I shows a schematic diagram of the parameters of the light-shielding film layer 160 in the first embodiment of the first embodiment according to FIG. 1E, and FIG. 1J shows the first implementation according to FIG. 1E The schematic diagram of the parameters of the light-shielding film layer 160 in the second embodiment of the method, the schematic diagram of the parameters of the light-shielding film layer 160 in the third embodiment of the first embodiment according to the first embodiment shown in FIG. 1E is shown in FIG. The schematic diagram of the parameters of the light-shielding film layer 160 in the fourth embodiment of the first embodiment is shown in FIG. 1M, and the parameter diagram of the light-shielding film layer 160 in the fifth embodiment of the first embodiment shown in FIG. 1E is shown in FIG. 1N. A schematic diagram of parameters of the light-shielding film layer 160 in the sixth embodiment according to the first embodiment shown in FIG. 1E is shown. It can be seen from FIG. 1I to FIG. 1N that the compensating part 163 is closer to the optical effective region 172 than the main part 162, the compensating part 163 extends toward the direction close to the optical effective region 172, and the compensating part 163 has a lower optical density than the main part 162 .

Please refer to Fig. 10 to Fig. 1V, wherein Fig. 1O shows the parameter diagram of the light-shielding film layer 160 in the seventh embodiment according to the first embodiment shown in Fig. 1E, and Fig. 1P shows the first implementation according to Fig. 1E The schematic diagram of the parameters of the light-shielding film layer 160 in the eighth embodiment of the method, the schematic diagram of the parameters of the light-shielding film layer 160 in the ninth embodiment of the first embodiment according to the first embodiment shown in FIG. 1E is shown in FIG. The parameter schematic diagram of the light-shielding film layer 160 in the tenth embodiment of the first embodiment is shown in FIG. 1S, and the parameter schematic diagram of the light-shielding film layer 160 in the eleventh embodiment of the first embodiment shown in FIG. 1E is shown in FIG. 1T. It shows the parameter schematic diagram of the light-shielding film layer 160 in the twelfth embodiment of the first embodiment in accordance with Fig. 1E, and Fig. 1U shows the parameters of the light-shielding film layer 160 in the thirteenth embodiment of the first embodiment in accordance with Fig. 1E Parameter schematic diagram, FIG. 1V shows a parameter schematic diagram of the light-shielding film layer 160 in the fourteenth embodiment according to the first embodiment shown in FIG. 1E . It can be seen from Fig. 10 to Fig. 1V that the compensating portion 163 extends toward the direction close to the optical effective region 172, and the compensating portion 163 includes a tip 164 and a reverse slope 165, wherein the tip 164 is disposed at an end away from the main body portion 162, and the reverse slope 165 faces the light-transmitting surface 171 , the reverse slope 165 approaches the light-transmitting surface 171 from the tip 164 toward the main body 162 , and an air interlayer S is formed between the reverse slope 165 and the light-transmitting surface 171 . In this way, a light trap structure is formed between the compensation part 163 and the plastic lens 111 to reduce the generation of stray light.

The thickness of the main body portion 162 is T, and the extension distance of the compensation portion 163 is L, wherein the values in FIG. 1I to FIG. 1V satisfy the conditions in Table 2 below. Table II T (um) L (um) tan ^-1 (T/L) (degrees) Figure 1I 3.2 10.6 16.8 Figure 1J 3.0 9.9 16.86 Figure 1K 2.5 8.3 16.76 Figure 1L 2.1 10.5 11.31 Figure 1M 1.9 9.0 11.92 Figure 1N 6.2 20.8 16.6 Figure 1O 2.9 11.8 13.81 Figure 1P 2.5 6.2 21.96 Figure 1Q 2.9 5.7 26.97 Figure 1R 2.6 5.8 24.15 Figure 1S 2.6 4.5 30.02 Figure 1T 5.2 5.2 45 Figure 1U 2.5 3.4 36.33 Figure 1V 3.0 3.4 41.42

In the first embodiment, the image sensor 150 is used to define a maximum image height, and the imaging lens 110 corresponds to the maximum image height to define a relative illuminance and a half viewing angle. The maximum image height of the camera module 10 is ImgH, and the imaging lens 110 The relative illuminance is RI, the half angle of view is HFOV; the optical density of the main body 162 is DM; the thickness of the main body 162 is T; the roughness of the main body 162 is RM; the roughness of the light-transmitting surface 171 is RO, and the parameters satisfy The following table three conditions. Table 3. The first embodiment ImgH (mm) 3.28 DM/T (um ^-1 ) 0.7 RI (%) 27.9 HFOV (degrees) 41.75 DM 5.6 RI×sin(HFOV) 0.19 T (um) 8 RM(um) 0.054 RO(um) 0.061 |1-RO/RM| 0.13

<Second Embodiment>

Please refer to FIG. 2A to FIG. 2C, wherein FIG. 2A shows a schematic diagram of the camera module 20 according to the second embodiment of the disclosure, and FIG. 2B shows the imaging lens 210 according to the second embodiment of FIG. 2A. As a perspective view, FIG. 2C shows an exploded view of the imaging lens 210 in the second embodiment according to FIG. 2B. 2A to 2C, the camera module 20 includes an imaging lens 210, a carrier element 230, a filter element 240 and an image sensor 250, wherein an optical axis X passes through the imaging lens 210, and the image The sensor 250 is disposed on the image side of the imaging lens 210 .

Imaging lens 210 includes plastic lens 211, spacer element 221, plastic lens 212, spacer element 222, plastic lens 213, spacer element 223, plastic lens 214, spacer element 224, plastic lens 215, spacer element from object side to image side in sequence 225 , plastic lens 216 , fixing element 226 , wherein the plastic lenses 211 , 212 , 213 , 214 , 215 , 216 , spacer elements 221 , 222 , 223 , 224 , 225 , and fixing element 226 are disposed in the carrier element 230 . It must be noted that the number, structure, surface shape and other optical characteristics of the plastic lens and each optical element can be configured according to different imaging requirements, and it is not limited thereto.

Please refer to FIG. 2D and FIG. 2E, wherein FIG. 2D shows a schematic diagram of the plastic lens 216 according to the second embodiment in FIG. 2C, and FIG. 2E shows another plastic lens 216 according to the second embodiment in FIG. 2C. A schematic diagram. It can be seen from Figures 2B to 2E that the light-shielding film layer 260 is disposed on a light-transmitting surface 271 of the plastic lens 216, and the plastic lens 216 includes an optically effective area 272 and an injection mark 275, wherein an edge of the light-shielding film layer 260 The area 261 forms a specific shape around the optical effective area 272, so that the light-shielding film layer 260 is used to define a light-transmitting area, and the light-transmitting area corresponds to the optical effective area 272, and the injection marks 275 are arranged on the outer periphery of the plastic lens 216 (not shown in the figure). ). It must be noted that, in order to clearly show the position and range of the light-shielding film layer 260 , the thickness of the light-shielding film layer 260 in FIG. 2D is not the actual thickness.

Moreover, the light-transmitting surface 271 includes a ring-shaped marking structure 273 and two inflection points I, wherein the plastic lens 216 includes an aspheric surface, and the aspheric surface corresponds to the optical effective area 272 . In detail, the ring-shaped marking structure 273 can surround the optical effective area 272 integrally, and the ring-shaped marking structure 273 can be used as an alignment mark and boundary when covering the light-shielding film layer 260, and can also be used as a detection optical effective area 272 Datum of offset or alignment mark for assembly, but not limited to. Thereby, the overall optical quality of the imaging lens 210 can be improved.

Please refer to FIG. 2F , which shows a schematic diagram of the compensating portion 263 of the light-shielding film layer 260 in the second embodiment according to FIG. 2E . It can be seen from FIG. 2D to FIG. 2F that the edge region 261 includes a main body portion 262 and a compensation portion 263, wherein the main body portion 262 is in physical contact with the light-transmitting surface 271, the main body portion 262 forms a specific shape, and the compensation portion 263 is disposed on the main body Portion 262 adjoins the edge of optically active area 272 .

Specifically, the compensating part 263 in FIG. 2F can improve the defect P in the prior art as shown in FIG. 8E. In this way, the compensating part 263 has a function of pre-compensation, which can eliminate random defects that may occur in the main body part 262 , so as to ensure the light-shielding function of the light-shielding film layer 260 .

In the second embodiment, the image sensor 250 is used to define a maximum image height, and the imaging lens 210 corresponds to the maximum image height to define a relative illuminance and a half viewing angle. The maximum image height of the camera module 20 is ImgH, and the imaging lens 210 The relative illuminance is RI, the half viewing angle is HFOV; the optical density of the main body 262 is DM; the thickness of the main body 262 is T; the roughness of the main body 262 is RM; the roughness of the light-transmitting surface 271 is RO, and the parameters satisfy The following table four conditions. Table 4. The second embodiment ImgH (mm) 3.28 DM/T (um ^-1 ) 1.3 RI (%) 27.9 HFOV (degrees) 41.75 DM 6.11 RI×sin(HFOV) 0.19 T (um) 4.7 RM (um) 0.536 RO(um) 0.539 |1-RO/RM| 0.006

It must be noted that the second embodiment and the first embodiment are the same camera module system, and the first embodiment and the second embodiment are used to illustrate the situation that different plastic lenses are provided with a light-shielding film layer.

In addition, the second embodiment is the same as the first embodiment in terms of structure and arrangement of other elements, so it will not be repeated here.

<Third Embodiment>

Please refer to FIG. 3A and FIG. 3B, wherein FIG. 3A shows a schematic diagram of the camera module 30 according to the third embodiment of the disclosure, and FIG. 3B shows the disassembly of the imaging lens in the third embodiment according to FIG. 3A picture. 3A and 3B, the camera module 30 includes an imaging lens (not shown), a carrier element 330 and an image sensor 350, wherein the image sensor 350 is disposed on the image side of the imaging lens.

The imaging lens includes plastic lens 311, spacer elements 321, 322, plastic lens 312, spacer element 323, plastic lens 313, spacer element 324, plastic lens 314, fixed element 325, plastic reflective element 380, The fixing element 326 , wherein the plastic lenses 311 , 312 , 313 , 314 , the spacing elements 321 , 322 , 323 , 324 , the fixing elements 325 , 326 and the plastic reflection element 380 are disposed in the carrier element 330 . It must be noted that the number, structure, surface shape and other optical characteristics of the plastic lens and each optical element can be configured according to different imaging requirements, and it is not limited thereto.

Specifically, the light passes through the plastic lens 311, the spacing elements 321, 322, the plastic lens 312, the spacing element 323, the plastic lens 313, the spacing element 324, the plastic lens 314, the fixing element 325 along the first optical axis X1, and the plastic The reflective element 380 is used to deflect the light so that the light enters the image sensor 350 along the second optical axis X2.

Please refer to FIG. 3C and FIG. 3D, wherein FIG. 3C shows a schematic diagram of the plastic reflective element 380 according to the third embodiment shown in FIG. 3B, and FIG. 3D shows the plastic reflective element 380 according to the third embodiment shown in FIG. 3B. Another schematic diagram of the reflective surface 381. It can be seen from FIG. 3C and FIG. 3D that the light-shielding film layer 360 is disposed on a light-transmitting surface 371 of the plastic reflective element 380, and the plastic reflective element 380 includes an optically effective area 372, an injection mark 375 and at least one reflective surface 381, Wherein an edge area 361 of the light-shielding film layer 360 forms a specific shape around the optical effective area 372, so that the light-shielding film layer 360 is used to define a light-transmitting area, the light-passing area corresponds to the optically effective area 372, and the injection marks 375 are arranged on the plastic reflective element 380 (not shown), and the reflective surface 381 and the optical effective area 372 are arranged on the same optical path. It must be noted that, in order to clearly show the position and range of the light-shielding film layer 360 , the thickness of the light-shielding film layer 360 in FIG. 3D is not the actual thickness.

Please refer to FIG. 3E , which shows a schematic diagram of the plastic reflective element 380 , the plastic injection mold and the ring-shaped marking structure 373 according to the third embodiment of FIG. 3B . It can be seen from FIG. 3D and FIG. 3E that the transparent surface 371 includes a ring-shaped marking structure 373 . In detail, the ring-shaped mark structure 373 can surround the optical effective area 372 integrally, and the ring-shaped mark structure 373 can be used as an alignment mark and boundary when covering the light-shielding film layer 360, and can also be used as a detection optical effective area 372 Datum of offset or alignment mark for assembly, but not limited to. Thereby, the overall optical quality of the imaging lens can be improved. Furthermore, in order to form different surface topography, plastic injection molding molds (not shown in the figure) can be formed by combining multiple upper molds M1, M2 and lower molds M3, M4, and the ring-shaped marking structure 373 corresponds to the upper molds M1, M2 and The demoulding directions of the lower molds M3 and M4 make the ring-shaped marking structure 373 integrally formed on the plastic reflective element 380 . In this way, the relative position of the ring-shaped marking structure 373 and other components can be guaranteed.

Please refer to FIG. 3F , which shows a schematic diagram of the compensation portion 363 of the light-shielding film layer 360 in the third embodiment according to FIG. 3D . It can be seen from Figure 3D and Figure 3F that the edge region 361 includes a main body 362 and a compensating part 363, wherein the main body 362 is in physical contact with the light-transmitting surface 371, the main body 362 forms a specific shape, and the compensating part 363 is disposed on the main body Portion 362 is adjacent to the edge of optically active area 372 .

Specifically, the compensating part 363 in FIG. 3F can improve the defect P in the prior art as shown in FIG. 8F. In this way, the compensating part 363 has a function of pre-compensation, which can eliminate random defects that may occur in the main body part 362 , so as to ensure the light-shielding function of the light-shielding film layer 360 .

The maximum extension distance of the compensating part 363 is Lmax, the area of the compensating part 363 is A, and the thickness of the main body part 362 is T, wherein Lmax/√(A) of Fig. 3F is 0.23, and tan ^-1 (T/Lmax) is 17.6 degrees.

In the third embodiment, the image sensor 350 is used to define a maximum image height, and the corresponding maximum image height of the imaging lens is used to define a relative illuminance and a half viewing angle. The maximum image height of the camera module 30 is ImgH, and the relative height of the imaging lens The illuminance is RI, the half angle of view is HFOV; the optical density of the main body 362 is DM; the thickness of the main body 362 is T; the maximum extension distance of the compensation part 363 is Lmax; the roughness of the main body 362 is RM; The degree is RO; the area of the compensating part 363 is A, and the parameters satisfy the conditions in Table 5 below. Table 5. The third embodiment ImgH (mm) 3.07 DM/T (um ^-1 ) 1.4 RI (%) 90.3 HFOV (degrees) 10.15 DM 6.4 RI×sin(HFOV) 0.16 T (um) 4.6 Lmax(um) 14.4 RM(um) 0.008 RO(um) 0.005 |1-RO/RM| 0.38 A(um ² ) 3919.8

In addition, the maximum extension distance Lmax of the compensation part 363 and the thickness T of the main body part 362 in the third embodiment may be the extension distance L and thickness T of any one of the examples in the first embodiment, but not limited thereto.

<Fourth Embodiment>

Please refer to FIG. 4 , which shows a schematic diagram of an image module 40 according to a fourth embodiment of the present disclosure. It can be seen from FIG. 4 that the image module 40 includes a lens (not shown in the figure) and an image source 450, wherein the image source 450 is arranged on the light-incident side of the lens, and the image is projected on the projection surface through the lens (not shown in the figure) .

In detail, the image module 40 is a single set of lenses, and the light from the image source 450 entering the lens can be converged or diverged. The image module 40 may further include an image transmission module (not shown in the figure), wherein the image transmission module may be a waveguide or an optical path turning mirror group, but not limited thereto. The image source 450 can be LCD, DLP, laser light source, ultraviolet light source or infrared light source, and the image source 450 can further include optical elements such as lens array, dodging sheet, glass slide, etc., but not limited thereto.

The lens includes lenses 411 , 412 , 413 , 414 , 415 sequentially from the light-incident side to the light-outside, wherein the lenses 411 , 412 , 413 , 414 , 415 are disposed in a carrier element 430 . Moreover, the lens 411 is a glass lens, and the lens 413 is a plastic lens, wherein the lens 411 is closer to the image source 450 than the lens 413 . In this way, the influence of the waste heat of the image source 450 on the optical properties of the plastic lens can be reduced to ensure the optical quality of the lens. It must be noted that the optical characteristics such as the number, structure, and surface shape of the lens and each optical element can be configured according to different imaging requirements, and it is not limited thereto.

Moreover, a light-shielding film layer (not shown in the figure) is disposed on a light-transmitting surface (not shown in the figure) of the lens 413, and the lens 413 includes an optically effective area (not shown in the figure), wherein an edge area of the light-shielding film layer (not shown in the figure) a specific shape is formed around the optical effective area, so that the light-shielding film layer is used to define a light-transmissive area, and the light-transmissive area corresponds to the optical effective area. Specifically, the edge area includes a main body (not shown in the figure), and the main body forms a specific shape.

The light-transmitting surface includes a ring-shaped mark structure (not shown in the figure), wherein the ring-shaped mark structure has an angle end, and the angle end surrounds the optically effective area, and the optically effective area of the light-transmitting surface is an aspheric surface, and the aspheric surface includes at least One inflection point.

In addition, the light-shielding film layer and other elements in the fourth embodiment are the same in structure and arrangement relationship as any light-shielding film layer and other corresponding elements in the first embodiment, and will not be repeated here.

<Fifth Embodiment>

Please refer to FIG. 5 , which shows a schematic diagram of an image module 50 according to a fifth embodiment of the present disclosure. As can be seen from FIG. 5 , the image module 50 includes lenses 510 , 551 and an image source 550 , wherein the image source 550 is disposed on the light incident side of the lens 510 , and the lens 551 is used to control the irradiation range of the image source 550 .

In detail, the image module 50 is a plurality of sets of lenses, and the light from the image source 550 entering the lens can be converged or diverged. The image module 50 may further include an image transmission module (not shown in the figure), wherein the image transmission module may be a waveguide or an optical path turning mirror group, but not limited thereto. The image source 550 can be LCD, DLP, laser light source, ultraviolet light source or infrared light source, and the image source 550 can further include optical elements such as lens array, dodging sheet, glass slide, etc., but not limited thereto.

The lens 510 sequentially includes lenses 511 , 512 , 513 , 514 , 515 from the light incident side to the light exit side, wherein the lenses 511 , 512 , 513 , 514 , 515 are disposed in a carrier element 530 . Moreover, the lens 511 is a glass lens, and the lens 513 is a plastic lens, wherein the lens 511 is closer to the image source 550 than the lens 513 . In this way, the influence of the waste heat of the image source 550 on the optical properties of the plastic lens can be reduced to ensure the optical quality of the lens. It must be noted that the optical characteristics such as the number, structure, and surface shape of the lens and each optical element can be configured according to different imaging requirements, and it is not limited thereto.

The lens 510 further includes a reflective element 580. Specifically, the lens 510 sequentially includes a reflective element 580 and lenses 511, 512, 513, 514, and 515 from the light incident side to the light output side, and the reflective element 580 is arranged between the lens 551 and the lens. 510 between lenses 511 . Thereby, the size of the image module 50 in one direction can be controlled.

Moreover, a light-shielding film layer (not shown in the figure) is disposed on a light-transmitting surface (not shown in the figure) of the lens 513, and the lens 513 includes an optically effective area (not shown in the figure), wherein an edge area of the light-shielding film layer (not shown in the figure) a specific shape is formed around the optical effective area, so that the light-shielding film layer is used to define a light-transmissive area, and the light-transmissive area corresponds to the optical effective area. Specifically, the edge area includes a main body (not shown in the figure), and the main body forms a specific shape.

The light-transmitting surface includes a ring-shaped mark structure (not shown in the figure), wherein the ring-shaped mark structure has an angle end, and the angle end surrounds the optically effective area, and the optically effective area of the light-transmitting surface is an aspheric surface, and the aspheric surface includes at least One inflection point.

In addition, the light-shielding film layer and other elements in the fifth embodiment are the same in structure and arrangement as any light-shielding film layer and other corresponding elements in the first embodiment and the fourth embodiment, and will not be repeated here.

<Sixth Embodiment>

Please refer to FIG. 6A to FIG. 6C, wherein FIG. 6A shows a schematic diagram of the electronic device 60 according to the sixth embodiment of the present disclosure, and FIG. 6B shows another electronic device 60 according to the sixth embodiment of FIG. 6A. A schematic diagram, FIG. 6C shows another schematic diagram of the electronic device 60 in the sixth embodiment according to FIG. 6A . It can be seen from FIG. 6A to FIG. 6C that the electronic device 60 is a smart phone, wherein the electronic device 60 can also be a notebook computer, a tablet computer, a driving recorder, etc., but not limited thereto. The electronic device 60 includes at least one camera module, an electronic photosensitive element (not shown in the figure) and an image capture control interface 610, wherein the camera module includes an imaging lens (not shown in the figure) and an image sensor (not shown in the figure). not shown). Specifically, the camera module can be the camera module of the aforementioned first embodiment to the third embodiment, but the present disclosure is not limited thereto.

In the sixth embodiment, the electronic device 60 includes super wide-angle camera modules 621, 622, super telephoto camera modules 623, wide-angle camera modules 624, 625, telephoto camera modules 626, TOF modules (Time-Of-Flight: time-of-flight ranging module) 627, macro camera module 628 and biometric sensing camera module 629, wherein TOF module 627 and biometric sensing camera module 629 can be other types of camera modules , is not limited to this configuration.

Specifically, in the sixth embodiment, the ultra-wide-angle camera module 621, the wide-angle camera module 624, the TOF module 627, and the biometric sensing camera module 629 are arranged on the front of the electronic device 60, and the ultra-wide-angle camera module The group 622 , the super telephoto camera module 623 , the wide-angle camera module 625 , the telephoto camera module 626 and the macro camera module 628 are arranged on the back of the electronic device 60 .

The image capture control interface 610 can be a touch screen, which is used to display images and has a touch function, and can be used to manually adjust the shooting angle. In detail, the image capture control interface 610 includes an image playback button 611 , a camera module switch button 612 , a focus and photograph button 613 , an integrated menu button 614 and a zoom control button 615 . Furthermore, the user enters the shooting mode through the image capture control interface 610 of the electronic device 60, and the camera module switch button 612 can freely switch between the ultra-wide-angle camera modules 621, 622, the super-telephoto camera module 623, and the wide-angle camera module. One of 624, 625, the telephoto camera module 626 and the macro camera module 628 are used for shooting. The zoom control key 615 is used to adjust the zoom. One of the telephoto camera module 623, the wide-angle camera modules 624, 625, the telephoto camera module 626, and the macro camera module 628 takes an image, and the image playback button 611 allows the user to watch the photo after the image is taken. The menu button 614 is used to adjust the details of image capture (such as timing photography, photographing ratio, etc.).

The electronic device 60 can further include a reminder light 63 , which is arranged on the front of the electronic device 60 and can be used to remind the user of unread messages, missed calls and mobile phone status.

Furthermore, after the user enters the shooting mode through the image capture control interface 610 of the electronic device 60, the camera module collects the image light on the electronic photosensitive element, and outputs electronic signals related to the image to the image signal processor of the single-chip system 65 (not shown in the figure), wherein the single-chip system 65 may further include a random access memory (RAM), a central processing unit and a storage unit (Storage Unit), and may further include but not limited to a display unit (Display), a control unit ( Control Unit), read-only storage unit (ROM) or a combination thereof.

In response to the camera specifications of the electronic device 60, the electronic device 60 may further include an optical anti-shake component (not shown) and an image software processor (not shown), further, the electronic device 60 may further include at least one focusing aid The element 66 and at least one sensing element (not shown). The focus assisting element 66 may include a light emitting element 661 for compensating color temperature, an infrared distance measuring element (not shown in the figure), a laser focusing module (not shown in the figure), etc., and the sensing element may have the ability to sense physical momentum and motion energy. Functions, such as accelerometers, gyroscopes, Hall Effect Elements, position locators, and signal transmission modules, to sense the shaking and shaking imposed by the user's hand or the external environment, thereby benefiting the electronic device 60 The autofocus function and the optical anti-shake component of the camera module are used to obtain good image quality, which helps the electronic device 60 according to this disclosure to have multiple modes of shooting functions, such as optimized self-timer, low-light HDR (High Dynamic Range, high dynamic range imaging), high-resolution 4K (4K Resolution) video recording, etc. In addition, the user can directly observe the shooting screen of the camera through the image capture control interface 610 , and manually operate the viewfinder range on the image capture control interface 610 to achieve the automatic focus function of what you see is what you get.

Furthermore, the camera module, electronic photosensitive element, optical anti-shake component, sensing element and focus assisting element 66 can be arranged on a circuit board 64 and electrically connected to related elements such as an image signal processor through a connector 641 To execute the shooting process, the circuit board 64 may be a flexible printed circuit board (FPC). The current electronic devices such as smart phones have a thinner and thinner trend. The camera module and related components are arranged on the circuit board, and then the circuit is integrated to the main board of the electronic device by using a connector, which can meet the mechanism design and the limited space inside the electronic device. The circuit layout requires and obtains a greater margin, which also enables the autofocus function of the camera module to be controlled more flexibly through the touch screen of the electronic device. In the sixth embodiment, the sensing element and the focusing auxiliary element 66 are arranged on a flexible circuit board (not shown in the figure), and are electrically connected to related elements such as imaging signal processing elements through corresponding connectors to execute the shooting process. In other embodiments (not shown in the figure), the sensing element and the auxiliary optical element can also be arranged on the main board of the electronic device or other types of carrier boards according to the mechanism design and circuit layout requirements.

Please refer to FIG. 6D , which shows a schematic diagram of an image of the electronic device 60 in the sixth embodiment according to FIG. 6A . It can be seen from FIG. 6D that the imaging results of the ultra-wide-angle camera modules 621 and 622 may have a larger viewing angle and depth of field than the wide-angle camera modules 624 and 625, but are often accompanied by greater distortion. Specifically, the viewing angle of Figure 6D is 105 degrees to 125 degrees, and the equivalent focal length is 11 mm to 14 mm.

Please refer to FIG. 6E , which shows another schematic image of the electronic device 60 in the sixth embodiment according to FIG. 6A . It can be seen from FIG. 6E that the wide-angle camera modules 624 and 625 can capture images with a certain range and high resolution, and have the function of high resolution and low distortion. Specifically, Figure 6E is a partially enlarged view of Figure 6D, the viewing angle of Figure 6E is 70 degrees to 90 degrees, and the equivalent focal length is 22 mm to 30 mm.

Please refer to FIG. 6F , which shows another schematic image of the electronic device 60 in the sixth embodiment according to FIG. 6A . It can be seen from FIG. 6F that the imaging result of the telephoto camera module 626 can have a smaller viewing angle and depth of field than the wide-angle camera modules 624 and 625, and can be used to photograph moving objects, that is, the actuator of the electronic device 60 (not shown in the figure). The telephoto camera module 626 can be driven to perform fast and continuous auto focus on the target, so that the target object will not be blurred due to being far away from the focus position. Specifically, Figure 6F is a partially enlarged view of Figure 6E, the viewing angle of Figure 6F is 10 degrees to 40 degrees, and the equivalent focal length is 60 mm to 300 mm.

Please refer to FIG. 6G , which shows another schematic image of the electronic device 60 in the sixth embodiment according to FIG. 6A . It can be seen from Figure 6G that the imaging result of the super telephoto camera module 623 has a smaller viewing angle and depth of field than that of the telephoto camera module 626, making the super telephoto camera module 623 easy to lose focus due to shaking, so the actuator provides the driving force While making the super-telephoto camera module 623 focus on the target, it can provide a feedback force for correcting shaking to achieve the effect of optical anti-shaking. Specifically, Figure 6G is a partially enlarged view of Figure 6E, the viewing angle of Figure 6G is 4 degrees to 8 degrees, and the equivalent focal length is 400 mm to 600 mm.

It can be seen from FIG. 6D to FIG. 6G that the electronic device 60 can realize the zooming function by using camera modules with different focal lengths to frame the view, and with the image processing technology. It must be noted that the equivalent focal length is an estimated value after conversion, and the actual focal length may vary due to the design of the camera module and the size of the electronic photosensitive element.

<Seventh Embodiment>

Please refer to FIG. 7A and FIG. 7B, wherein FIG. 7A shows an application diagram of the electronic device 70 according to the seventh embodiment of the disclosure, and FIG. 7B shows the electronic device 70 according to the seventh embodiment shown in FIG. 7A Projection diagram. It can be seen from FIG. 7A and FIG. 7B that the electronic device 70 is a head-mounted device, wherein the head-mounted device can be an augmented reality (AR) module or a virtual reality (VR) module. Furthermore, the electronic device 70 can also be a projection module, a Lidar module, etc., but not limited thereto. Thereby, the resolution of the projected graphics can be improved.

The electronic device 70 includes two image modules 700 , wherein the image modules 700 respectively include an image transfer module 720 , a lens 710 and an image source 750 . Specifically, the image module 700 can be the image module of the aforementioned fourth embodiment and the fifth embodiment, and the image transfer module 720 can be a waveguide, and the lens 710 can be a projection lens, but this disclosure does not limit.

The image module 700 can be a single set of lenses or multiple sets of lenses. The light from the image source 750 entering the lens 710 can be converged or diverged to the projection surface 701 . The image source 750 may further include optical elements such as a lens array, dodging sheet, glass slide, etc., but is not limited thereto.

Moreover, the image transmission module 720 is disposed on the light-incident side of the image module 700 , and through the configuration of the image transmission module 720 , the optical path of the imaging light IL of the image source 750 can be turned and transmitted to the user's eyes.

Although the present invention has been disclosed above with examples and implementation methods, it is not intended to limit the present invention. Anyone with ordinary knowledge in the technical field may make some modifications and changes without departing from the spirit and scope of the present invention. Modification, so the scope of protection of the present invention should be defined by the scope of the appended patent application.

10,20,30: camera module 110,210: imaging lens 111,112,113,114,115,116,211,212,213,214,215,216,311,312,313,314: plastic lens 121,122,123,124,125,221,222,223,224,225,321,322,323,324: spacer elements 126, 226, 325, 326: fixed elements 130, 230, 330, 430, 530: Carrier elements 140,240: filter elements 150,250,350: image sensor 160,260,360,860: shading film layer 161,261,361: fringe area 162,262,362,862: main body 163,263,363: Department of Compensation 164: tip 165: reverse bevel 171,271,371,871: Translucent surface 172,272,372: optical effective area 173,273,373: Cyclic labeling structures 174: angle end 175,275,375: injection marks 380: Plastic reflective element 40,50,700: video module 411,412,413,414,415,511,512,513,514,515: lens 450,550,750: image source 510,551,710: Lens 580: reflective element 60,70: Electronics 610: Image acquisition control interface 611: Image playback button 612:Camera module switching button 613: Focus camera button 614: Integrated menu button 615: Zoom control key 621,622:Ultra wide-angle camera module 623:Super telephoto camera module 624,625: Wide-angle camera modules 626: Telephoto camera module 627:TOF module 628:Macro camera module 629:Camera module for biometric sensing 63: Reminder light 64: circuit board 641: Connector 65:Single chip system 66:Focus Assist Components 661: Light emitting element 701: projection surface 720: Image transfer module S: air interlayer I: inflection point IL: imaging light M1, M2: upper mold M3, M4: Lower mold X: optical axis X1: the first optical axis X2: second optical axis P,P1,P2,P2',P3: defects N: The number of plastic lenses in the lens ImgH: the maximum image height of the lens RI: relative illuminance of the lens HFOV: half angle of view of the lens L: The extension distance of the compensation part Lmax: the maximum extension distance of the compensation part A: The area of the compensation part T: Thickness of the main body DM: optical density of the main body

FIG. 1A shows a schematic diagram of a camera module according to a first embodiment of the disclosure; FIG. 1B shows a perspective view of the imaging lens in the first embodiment according to FIG. 1A; FIG. 1C shows an exploded view of the imaging lens in the first embodiment according to FIG. 1B; FIG. 1D shows a schematic diagram of the plastic lens in the first embodiment according to FIG. 1C; FIG. 1E shows a schematic diagram of the light-shielding film layer in the first embodiment according to FIG. 1D; FIG. 1F shows a schematic diagram of the light-shielding film layer in the first embodiment according to FIG. 1E; FIG. 1G shows a schematic diagram of the compensation part of the light-shielding film layer according to the first embodiment of FIG. 1E; FIG. 1H shows another schematic diagram of the compensation part of the light-shielding film layer in the first embodiment according to FIG. 1E; FIG. 1I shows a schematic diagram of the parameters of the light-shielding film layer in the first embodiment according to the first embodiment in FIG. 1E; FIG. 1J shows a schematic diagram of the parameters of the light-shielding film layer in the second example of the first embodiment in FIG. 1E; FIG. 1K shows a schematic diagram of the parameters of the light-shielding film layer in the third embodiment according to the first embodiment in FIG. 1E; FIG. 1L shows a schematic diagram of the parameters of the light-shielding film layer in the fourth embodiment of the first embodiment in FIG. 1E; FIG. 1M shows a schematic diagram of the parameters of the light-shielding film layer in the fifth example of the first embodiment in FIG. 1E; FIG. 1N shows a schematic diagram of the parameters of the light-shielding film layer in the sixth example of the first embodiment in FIG. 1E; FIG. 10 shows a schematic diagram of the parameters of the light-shielding film layer in the seventh embodiment according to the first embodiment in FIG. 1E; FIG. 1P shows a schematic diagram of the parameters of the light-shielding film layer in the eighth embodiment according to the first embodiment in FIG. 1E; FIG. 1Q shows a schematic diagram of the parameters of the light-shielding film layer in the ninth example of the first embodiment in FIG. 1E; FIG. 1R shows a schematic diagram of the parameters of the light-shielding film layer in the tenth embodiment according to the first embodiment in FIG. 1E; FIG. 1S shows a schematic diagram of the parameters of the light-shielding film layer in the eleventh embodiment of the first embodiment in FIG. 1E; FIG. 1T shows a schematic diagram of the parameters of the light-shielding film layer in the twelfth embodiment of the first embodiment in FIG. 1E; Figure 1U shows a schematic diagram of the parameters of the light-shielding film layer in the thirteenth embodiment of the first embodiment in Figure 1E; FIG. 1V shows a schematic diagram of the parameters of the light-shielding film layer in the fourteenth embodiment of the first embodiment in FIG. 1E; FIG. 2A shows a schematic diagram of a camera module according to a second embodiment of the disclosure; FIG. 2B shows a perspective view of the imaging lens in the second embodiment according to FIG. 2A; FIG. 2C shows an exploded view of the imaging lens in the second embodiment according to FIG. 2B; FIG. 2D shows a schematic diagram of the plastic lens in the second embodiment according to FIG. 2C; FIG. 2E shows another schematic diagram of the plastic lens in the second embodiment according to FIG. 2C; FIG. 2F shows a schematic diagram of the compensation part of the light-shielding film layer according to the second embodiment of FIG. 2E; FIG. 3A shows a schematic diagram of a camera module according to a third embodiment of the disclosure; FIG. 3B shows an exploded view of the imaging lens in the third embodiment according to FIG. 3A; FIG. 3C shows a schematic diagram of the plastic reflective element in the third embodiment according to FIG. 3B; FIG. 3D shows another schematic diagram of the plastic reflective element in the third embodiment according to FIG. 3B; FIG. 3E shows a schematic diagram of the plastic reflective element, the plastic injection mold and the ring-shaped marking structure according to the third embodiment of FIG. 3B; FIG. 3F shows a schematic diagram of the compensation part of the light-shielding film layer according to the third embodiment of FIG. 3D; FIG. 4 shows a schematic diagram of an image module according to a fourth embodiment of the disclosure; FIG. 5 shows a schematic diagram of an image module according to a fifth embodiment of the disclosure; FIG. 6A shows a schematic diagram of an electronic device according to a sixth embodiment of the present disclosure; FIG. 6B shows another schematic diagram of the electronic device in the sixth embodiment according to FIG. 6A; FIG. 6C shows another schematic diagram of the electronic device in the sixth embodiment according to FIG. 6A; FIG. 6D shows a schematic diagram of an image of the electronic device in the sixth embodiment according to FIG. 6A; FIG. 6E shows another schematic image of the electronic device in the sixth embodiment according to FIG. 6A; FIG. 6F shows another schematic image of the electronic device in the sixth embodiment according to FIG. 6A; FIG. 6G shows another schematic image of the electronic device in the sixth embodiment according to FIG. 6A; FIG. 7A shows a schematic diagram of the application of the electronic device according to the seventh embodiment of the present disclosure; FIG. 7B shows a schematic projection diagram of the electronic device in the seventh embodiment according to FIG. 7A; FIG. 8A shows a schematic diagram of a light-shielding film layer according to the prior art; FIG. 8B shows another schematic diagram of the light-shielding film layer according to the prior art; FIG. 8C shows another schematic diagram of the light-shielding film layer according to the prior art; FIG. 8D shows another schematic diagram of the light-shielding film layer according to the prior art; FIG. 8E shows another schematic diagram of the light-shielding film layer according to the prior art; and FIG. 8F shows another schematic diagram of the light-shielding film layer according to the prior art.

10: Camera module

110: imaging lens

111,112,113,114,115,116: plastic lens

121, 122, 123, 124, 125: spacer elements

126: fixed element

130: carrier element

140: filter element

150: image sensor

X: optical axis

Claims (54)

A camera module, comprising: an imaging lens, comprising: a plastic optical element, a light-shielding film layer disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, the light-shielding film layer An edge area forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-transmissive area corresponding to the optical effective area, wherein the edge area includes: a main body, and the light-transmissive The surface is in physical contact; and a compensating portion is disposed on the edge of the main body adjacent to the optical effective area, the compensating portion is closer to the optical effective area than the main body, the compensating portion extends toward the direction close to the optical effective area, and the The compensation part has a lower optical density than the main part; and an image sensor is arranged on an image side of the imaging lens, and the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height Used to define a relative illuminance; wherein, the roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um; wherein, the light-transmitting surface includes a ring-shaped marking structure, the ring-shaped marking structure has an angle end, and The angle end surrounds the optical effective area; wherein, the relative illuminance of the imaging lens is RI, the optical density of the main body is DM, a thickness of the main body is T, an extension distance of the compensation part is L, and The following conditions are met: - LOG(RI)/DM ≤ 1.2; 3 degrees ≤ tan ^-1 (T/L) ≤ 89.5 degrees; 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 ; and 0 um < L ≤ 32 um. The camera module as described in claim 1, wherein the imaging lens corresponds to the maximum image height to define a half angle of view, the half angle of view is HFOV, the relative illuminance of the imaging lens is RI, and it satisfies the following conditions: 0.04 ≤ RI×sin(HFOV) ≤ 0.35. The camera module as described in claim 1, wherein the thickness of the main body is T, which satisfies the following conditions: 0.14um ≤ T ≤ 9.85um. The camera module as described in claim 3, wherein the thickness of the main body is T, which satisfies the following conditions: 0.28um ≤ T ≤ 4.95um. The camera module as described in claim 4, wherein the thickness of the main body is T, which satisfies the following conditions: 0.48um ≤ T ≤ 1.95um. The camera module as described in claim 1, wherein the extension distance of the compensation part is L, which satisfies the following conditions: 0um < L ≤ 16um. The camera module as claimed in item 6, wherein the extension distance of the compensation part is L, which satisfies the following conditions: 0 um < L ≤ 7 um. The camera module according to Claim 1, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions are met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 . The camera module as described in Claim 1, wherein the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6. The camera module according to claim 1, wherein the plastic optical element is a plastic lens, the plastic lens includes an aspheric surface, and the aspheric surface corresponds to the optically effective area. The camera module according to claim 1, wherein the plastic optical element is a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the at least one reflective surface and the optical effective area are arranged on the same optical path. An electronic device comprising: At least one camera module as described in claim 1. A camera module, comprising: an imaging lens, comprising: a plastic optical element, a light-shielding film layer disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, the light-shielding film layer An edge area forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-transmissive area corresponding to the optical effective area, wherein the edge area includes: a main body, and the light-transmissive The surface is in physical contact; and a compensating portion is disposed on the edge of the main body adjacent to the optical effective area, the compensating portion is closer to the optical effective area than the main body, the compensating portion extends toward the direction close to the optical effective area, and the The compensation part has a lower optical density than the main part; and an image sensor is arranged on an image side of the imaging lens, and the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height Used to define a relative illuminance; wherein, the roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um; wherein, the light-transmitting surface includes a ring-shaped marking structure, the ring-shaped marking structure has an angle end, and The angle end surrounds the optical effective area; wherein, the relative illuminance of the imaging lens is RI, the optical density of the main body is DM, a thickness of the main body is T, and a maximum extension distance of the compensation part is Lmax, An area of the compensation part is A, which satisfies the following conditions: - LOG(RI)/DM ≤ 1.2; 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 ; 0 um < Lmax ≤ 32 um; and 0 < Lmax /√(A) ≤ 0.98. The camera module as described in claim 13, wherein the imaging lens corresponds to the maximum image height to define a half angle of view, the half angle of view is HFOV, the relative illuminance of the imaging lens is RI, and it satisfies the following conditions: 0.04 ≤ RI×sin(HFOV) ≤ 0.35. The camera module as claimed in item 13, wherein the thickness of the main body part is T, the maximum extension distance of the compensation part is Lmax, which satisfies the following conditions: 3 degrees ≤ tan ^-1 (T/Lmax) ≤ 89.5 Spend. The camera module according to claim 13, wherein the maximum extension distance of the compensation part is Lmax, which satisfies the following conditions: 0um < Lmax ≤ 16um. The camera module as claimed in item 16, wherein the maximum extension distance of the compensation part is Lmax, which satisfies the following conditions: 0um < Lmax ≤ 7um. The camera module as described in claim 13, wherein the thickness of the main body is T, which satisfies the following conditions: 0.14um ≤ T ≤ 9.85um. The camera module as claimed in item 18, wherein the thickness of the main body is T, which satisfies the following conditions: 0.28um ≤ T ≤ 4.95um. The camera module as claimed in item 19, wherein the thickness of the main body is T, which satisfies the following conditions: 0.48um ≤ T ≤ 1.95um. The camera module according to claim 13, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions are met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 . The camera module as claimed in item 13, wherein the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6. The camera module according to claim 13, wherein the plastic optical element is a plastic lens, the plastic lens includes an aspheric surface, and the aspherical surface corresponds to the optically effective area. The camera module according to claim 13, wherein the plastic optical element is a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the at least one reflective surface and the optical effective area are arranged on the same optical path. An electronic device comprising: At least one camera module as described in claim 13. A camera module, comprising: an imaging lens, comprising: a plastic optical element, a light-shielding film layer disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, the light-shielding film layer An edge area forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-transmissive area corresponding to the optical effective area, wherein the edge area includes: a main body, and the light-transmissive The surface is in physical contact; and a compensation part is arranged on the edge of the main body adjacent to the optical effective area, the compensation part is closer to the optical effective area than the main body, the compensation part extends toward the direction close to the optical effective area, and the compensation The portion has a lower optical density than the main body portion, and the compensating portion includes: a tip disposed at an end away from the main body; The direction of the main body is close to the light-transmitting surface, and an air interlayer is formed between the reverse slope and the light-transmitting surface; and an image sensor is arranged on an image side of the imaging lens, and the image sensor is used for To define a maximum image height, the imaging lens corresponds to the maximum image height to define a relative illuminance; wherein, the roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um; wherein, the light-transmitting surface includes a ring The ring-shaped mark structure has an angle end, and the angle end surrounds the optical effective area; wherein, the relative illuminance of the imaging lens is RI, the optical density of the main part is DM, and a part of the main part The thickness is T, and the extension distance of the compensation part is L, which satisfies the following conditions: -LOG(RI)/DM ≤ 1.2; 3 degrees ≤ tan ^-1 (T/L) ≤ 89.5 degrees; and 0 um < L ≤ 32um. The camera module as described in claim 26, wherein the imaging lens corresponds to the maximum image height to define a half angle of view, the half angle of view is HFOV, the relative illuminance of the imaging lens is RI, and it satisfies the following conditions: 0.04 ≤ RI×sin(HFOV) ≤ 0.35. The camera module as claimed in item 26, wherein the optical density of the main body is DM, the thickness of the main body is T, and it satisfies the following conditions: 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 . The camera module as claimed in item 28, wherein the optical density of the main body is DM, the thickness of the main body is T, and it satisfies the following conditions: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 . The camera module as claimed in item 26, wherein the extension distance of the compensation part is L, which satisfies the following conditions: 0um < L ≤ 16um. The camera module as claimed in item 30, wherein the extension distance of the compensation part is L, which satisfies the following conditions: 0 um < L ≤ 7 um. The camera module as claimed in claim 26, wherein the thickness of the main body is T, which satisfies the following conditions: 0.14um ≤ T ≤ 9.85um. The camera module as claimed in item 32, wherein the thickness of the main body is T, which satisfies the following conditions: 0.28um ≤ T ≤ 4.95um. The camera module as claimed in item 33, wherein the thickness of the main body is T, which satisfies the following conditions: 0.48um ≤ T ≤ 1.95um. The camera module as claimed in item 26, wherein the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6. The camera module as claimed in claim 26, wherein the plastic optical element is a plastic lens, the plastic lens includes an aspheric surface, and the aspheric surface corresponds to the optically effective area. The camera module according to claim 26, wherein the plastic optical element is a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the at least one reflective surface and the optical effective area are arranged on the same optical path. An electronic device comprising: At least one camera module as described in claim 26. A camera module, comprising: an imaging lens, comprising: a plastic optical element, a light-shielding film layer disposed on a light-transmitting surface of the plastic optical element, and the plastic optical element includes an optically effective area, the light-shielding film layer An edge area forms a specific shape around the optical effective area, so that the light-shielding film layer is used to define a light-transmitting area, and the light-transmitting area corresponds to the optical effective area, wherein the edge area includes: a main body forming the specific shape and an image sensor disposed on an image side of the imaging lens, the image sensor is used to define a maximum image height, and the imaging lens corresponds to the maximum image height to define a relative illuminance and a half viewing angle; wherein, The roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um; wherein, the light-transmitting surface includes a ring-shaped marking structure, the ring-shaped marking structure has an angled end, and the angled end surrounds the optically active area; Wherein, a thickness of the main body is T, the optical density of the main body is DM, the relative illuminance of the imaging lens is RI, and the half angle of view is HFOV, which satisfies the following conditions: -LOG(RI)/DM ≤ 1.2 ; 0.14 um ≤ T ≤ 9.85 um; 0.7 um ^-1 ≤ DM/T ≤ 7.2 um ^-1 ; and 0.04 ≤ RI×sin(HFOV) ≤ 0.35. The camera module as claimed in item 39, wherein the optical density of the main body is DM, the thickness of the main body is T, and it satisfies the following conditions: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 . The camera module as claimed in item 39, wherein the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6. The camera module as claimed in claim 39, wherein the plastic optical element is a plastic lens, the plastic lens includes an aspheric surface, and the aspherical surface corresponds to the optically effective area. The camera module according to claim 39, wherein the plastic optical element is a plastic reflective element, the plastic reflective element includes at least one reflective surface, and the at least one reflective surface and the optical effective area are arranged on the same optical path. An electronic device comprising: At least one camera module as described in claim 39. An image module, comprising: a lens, including a glass lens and a plastic lens; and an image source, disposed on a light-incident side of the lens; wherein, the glass lens is closer to the image source than the plastic lens; wherein, A light-shielding film layer is arranged on a light-transmitting surface of the plastic lens, and the plastic lens includes an optically effective area; wherein, an edge area of the light-shielding film layer forms a specific shape around the optically effective area, so that the light-shielding film The layer is used to define a light-transmitting area, and the light-transmitting area corresponds to the optically effective area; wherein, the roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um; wherein, the light-transmitting surface includes a ring-shaped marking structure, The ring-shaped marking structure has an angled end, and the angled end surrounds the optically effective area; wherein, the edge area includes a main body portion, forming the specific shape; wherein, a thickness of the main body portion is T, and the main body portion The optical density is DM, which satisfies the following conditions: 0.14 um ≤ T ≤ 9.85 um; and 0.7 um ⁻¹ ≤ DM/T ≤ 7.2 um ⁻¹ . The image module according to claim 45, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions are met: 1.6 um ^-1 ≤ DM/T ≤ 1.95 um ^-1 . The image module as described in claim 45, wherein the roughness of the transparent surface is RO, the roughness of the main body is RM, which meet the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6. The image module as claimed in claim 45, wherein the optically effective area of the transparent surface is an aspheric surface, and the aspheric surface includes at least one inflection point. An electronic device comprising: At least one image module as described in Claim 45. An image module, comprising: a lens, which sequentially includes a reflective element and a plastic lens from a light incident side to a light exit side; and an image source, arranged on the light incident side of the lens; wherein, a shading film A layer is disposed on a light-transmitting surface of the plastic lens, and the plastic lens includes an optically effective area; wherein, an edge area of the light-shielding film layer forms a specific shape around the optically effective area, so that the light-shielding film layer is used for Define a light-transmitting area, the light-transmitting area corresponds to the optical effective area; wherein, the roughness of the light-transmitting surface is RO, which is equal to or less than 1.2 um; wherein, the light-transmitting surface contains a ring-shaped marking structure, and the ring-shaped The marking structure has an angled end, and the angled end surrounds the optically active area; wherein, the edge area includes a main body portion forming the specific shape; wherein, a thickness of the main body portion is T, and an optical density of the main body portion is DM, which satisfies the following conditions: 0.14 um ≤ T ≤ 9.85 um; and 0.7 um ⁻¹ ≤ DM/T ≤ 7.2 um ⁻¹ . The image module according to claim 50, wherein the optical density of the main body is DM, the thickness of the main body is T, and the following conditions are met: 1.6 um ⁻¹ ≤ DM/T ≤ 1.95 um ⁻¹ . The image module as described in claim 50, wherein the roughness of the light-transmitting surface is RO, and the roughness of the main body is RM, which satisfy the following conditions: 0 ≤ |1-RO/RM| ≤ 0.6. The image module as claimed in claim 50, wherein the optically effective area of the transparent surface is an aspheric surface, and the aspheric surface includes at least one inflection point. An electronic device comprising: At least one image module as described in Claim 50.

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