KR102104081B1 - Camera structure, information and communication equipment - Google Patents

Abstract

A laminated structure of a cover glass that protects an internal structure of an imaging device, such as an information communication device, from the outside, a transparent substrate that transmits light, a near-infrared light absorbing film that absorbs light in the near-infrared region, and light in the near-infrared region. It provides a laminated structure of a cover glass, characterized in that it comprises a reflective near-infrared light reflection film. Accordingly, a new camera structure in which the optical filter is removed is provided.

Description

Camera structure, information and communication equipment

The present invention relates to a laminated structure of a cover glass provided in an imaging device.

In this century, imaging devices, that is, cameras, have become mainstream imaging devices using solid-state imaging elements (imaging elements), that is, digital cameras. In addition, recently, information communication devices such as personal computers (PCs), tablet PCs, and smart phones have been popularized and used for everyday use. Many of these information communication devices have a small camera module built in, and at present, they also have a high-performance pixel count of 10 million or more (see Fig. 11A). Information communication devices, especially smart phones, which are portable communication devices, tend to be thin and light, and the camera module as a component is also required to have a short length in the optical axis direction, and there is also a strong demand for downsizing and space saving.

In this specification, an internal mechanism of an imaging device essential for imaging is defined as a camera module, such as a lens unit including an optical lens group, a lens carrier, an imaging element, and a magnet holder. In addition, it is defined as a camera structure that the camera module includes a cover glass that protects the internal mechanism of the imaging device from outside.

As shown in Fig. 11B, the camera module 1 is mainly composed of a lens unit 50, a lens carrier 40, a magnet holder 30, an optical filter 60, and an imaging element 70. (For example, refer to Japanese Patent Application Publication No. 2013-153361). Among them, the optical filter mainly serves to cut light in the near infrared region. The human eye has sensitivity to visible light (visible light) with a wavelength of 380 nm to 780 nm. On the other hand, the imaging element generally includes visible light, and has a sensitivity to light having a longer wavelength, that is, light having a wavelength of about 1.1 μm. Therefore, if the image captured by the imaging element is taken as a photograph, it is not seen as a natural color tone in the human eye, and causes discomfort. Therefore, the camera module has been configured with a built-in optical filter (near infrared light cut filter) for cutting light in the near infrared region.

As the near-infrared light cut filter, for example, a glass containing phosphate or fluoride phosphate that absorbs light in the near-infrared region called blue glass is used.

As the demand for miniaturization and space saving of the camera module 1 is increasing as described above, the camera structure including the camera module 1 has a shorter and shorter length D1 (see FIG. 11 (B)). Efforts are being made. As a part of the optical filter 60, a thin one has been developed. The blue glass has low strength, so it is technically difficult to process a thin plate of 0.2 mm or less, and it is fragile. . In addition, if a foreign object in the form of particles, such as particles generated in the process of thin polishing or mounting process, falls on an imaging element disposed directly under the optical filter, it may cause image quality to deteriorate. Making a thin, low-particle, high-quality near-infrared cut filter with blue glass itself reduces yield and increases manufacturing costs. The present invention is to provide a new camera structure in which the optical filter is removed in light of this situation.

(1) The present invention is a laminated structure of a cover glass that protects the internal mechanism of an imaging device from outside, a transparent substrate that transmits light, a near-infrared light absorbing film that absorbs light in the near-infrared region, and near-infrared. It provides a laminated structure of a cover glass, characterized in that it comprises a near-infrared light reflection film that reflects the light in the region.

According to the invention of the above (1), the cover glass that protects the internal mechanism of an imaging device, such as a digital camera, can cut light in the near-infrared region and improve the image without embedding a near-infrared cut filter inside the camera. It shows the effect that can be obtained.

(2) The present invention provides a laminated structure of the cover glass according to (1) above, wherein the transparent substrate is crystallized glass.

According to the invention of (2) above, it is possible to manufacture a high-strength cover glass having good workability and high impact resistance.

(3) The present invention provides a laminated structure of the cover glass according to any one of (1) or (2) above, wherein the near infrared ray absorbing film contains an organic dye.

According to the invention of the above (3), it is possible to cut light in the near-infrared region without dependence on the angle of incidence with respect to light absorption, without using blue glass which is generally used as a material for a filter for absorbing light in the near-infrared region. It shows an effect.

(4) The present invention provides a laminated structure of the cover glass according to any one of (1) to (3), wherein the near-infrared light reflection film is a dielectric multilayer film.

The human eye is sensitive to so-called visible light with a wavelength of 380 nm to 780 nm. On the other hand, the imaging device generally has a longer wavelength, that is, a light having a wavelength of about 1.1 μm, including visible light. Therefore, if the image captured by the imaging element is taken as a photograph, it is not visible in a natural color tone and causes discomfort. According to the invention of the above (4), by providing a near-infrared light reflecting film made of a dielectric multilayer film, it is possible to obtain an image with a natural color tone by cutting light having a wavelength of 700 nm or more that is not absorbed by the near-infrared light absorbing film.

(5) The present invention is a multilayer structure of the cover glass according to (4), wherein the dielectric multilayer film is formed by stacking a plurality of types of oxide films having different refractive indices, and the adjacent oxide films are different types of oxide films. Provides

According to the invention of the above (5), by changing the material, film thickness, and number of layers constituting the oxide film, the effect of controlling the wavelength of the light to be reflected is exhibited.

(6) The present invention further comprises an antireflection film that reflects light in the ultraviolet region and suppresses reflection of light in the visible region. Lamination of the cover glass according to any one of (1) to (5) above, characterized in that it is further provided. Provide structure.

According to the invention of the above (6), since the cover glass protecting the camera in the device from the outside can cut the light in the ultraviolet region, it is possible to prevent deterioration by ultraviolet rays of the optical lens formed of synthetic resin as a component of the camera, , The anti-reflection function of light in the visible region allows more incident light to be received, so that a brighter image can be obtained.

(7) In the present invention, the anti-reflection film is a dielectric multilayer film, and the laminated structure of the cover glass according to (6) above is characterized in that the nitride film and the oxide film are alternately stacked.

Generally, the nitride film has a higher hardness than the oxide film. According to the invention of the above (7), by using a nitride film as a material constituting the antireflection film, an effect of increasing scratch resistance is exhibited.

(8) In the present invention, the anti-reflection film is formed on the incident side of light based on the transparent substrate, and the near-infrared light, in turn, from the farthest side of the transparent substrate, on the emitting side of light based on the transparent substrate. There is provided a laminated structure of the cover glass according to (6) or (7) above, wherein the reflective film and the near infrared ray absorbing film are formed.

According to the invention of the above (8), since the anti-reflection film for reflecting light in the ultraviolet region on the incident side of the light and suppressing the reflection of light in the visible region is provided, the near-infrared light absorbing film formed on the imaging element side than the anti-reflection film is ultraviolet. It prevents deterioration by light in the area. In addition, since the near-infrared light reflecting film is provided on the side farthest from the transparent substrate from the light emitting side, a substance that causes deterioration such as moisture does not easily penetrate the near-infrared light absorbing film formed on the transparent substrate side than the near-infrared reflecting film. Indicates.

(9) The present invention is to any one of the above (1) to (7) characterized in that it further comprises an antifouling (防汚) coating film to prevent contamination from the outside, on the outermost side of the light is incident. A laminated structure of the described cover glass is provided.

The cover glass of the imaging device has many opportunities for contamination, such as daily contact with clothes or fingers. When the cover glass is contaminated, deterioration of the image captured by the camera is caused. According to the invention of the above (9), by covering the outermost side of the cover glass with an antifouling coating film, it is easy to remove contamination, and an effect of always capturing an image of excellent image quality is exhibited.

(10) The present invention is characterized in that the imaging device is an information communication device, and the cover glass is continuously installed in a case of the information communication device. The laminated structure of the cover glass according to (1) to (9) is described. to provide.

According to the invention of the above (10), for example, a camera attached to an information communication device such as a tablet PC or a smart phone, an optical filter function is added to a cover glass, which has been mainly used to protect internal mechanisms from contamination and impact. By doing so, it is possible to cut the light in the near infrared region. In addition, there is a remarkable effect that an image enhancement can be obtained without embedding a near-infrared light cut filter inside the camera. This effect is particularly great for a camera module of a smart phone, which is a portable communication terminal with a strong request for miniaturization of the camera module.

(11) The present invention is a camera structure having a cover glass having a laminated structure of the cover glass described in (1) to (9) above, the optical lens group disposed on the cover glass side, the cover glass and the optical lens A camera structure comprising an imaging element that receives light incident through a group, and does not arrange a near-infrared light cut filter that cuts light in the near-infrared region between optical paths from the optical lens group to the imaging element. Provides

According to the invention of the above (11), since there is no need to embed the near infrared light cut filter, the length of the entire camera structure can be shortened and small, and the near infrared light cut filter is not disposed near the imaging element. In the manufacturing process of the cut filter, a remarkable effect that the foreign matter (particles) attached to the filter surface falls to the surface of the imaging element and does not deteriorate the image. In addition, in the assembly process of the camera module, a process for arranging and assembling the near-infrared light cut filter is also unnecessary, further contributing to cost reduction, yield improvement, and work efficiency.

(12) The present invention provides an imaging device characterized by having the camera structure described in (11) above.

According to the invention of the above (12), since light in the near-infrared region can be cut with a cover glass, it is possible to realize an imaging device equipped with a compact and inexpensive camera structure without a built-in near-infrared cut filter.

(13) The present invention is a laminated structure of a cover glass that protects the internal mechanism of an imaging device from outside, comprising a transparent substrate that transmits light and a near-infrared reflecting film that reflects light in the near-infrared region. A laminated structure of glass is provided.

According to the invention of the above (13), since the cover glass has a near-infrared light reflecting film that reflects light, it is possible to exhibit an effect of not allowing near-infrared light from outside to enter the internal mechanism of the imaging device. In addition, since it is not necessary to put a member having a near-infrared light reflection film in an area close to the imaging element, reflection of light incident on the internal mechanism of the imaging device can be suppressed, and consequently, stray light is suppressed, and ghost or It can have a remarkable effect of reducing the cause of flare.

(14) The present invention provides a laminated structure of the cover glass according to (13) above, which further comprises an antireflection film that reflects light in the ultraviolet region and further prevents reflection of light in the visible region.

According to the invention of the above (14), since the cover glass protecting the internal mechanism of the imaging device from the outside can cut the light in the ultraviolet region, deterioration by ultraviolet rays such as an optical lens formed of synthetic resin which is a component of the camera is prevented. It can be prevented to contribute to longevity. In addition, since the cover glass has an anti-reflection function that prevents reflection of light in at least a visible region, it exhibits a remarkable effect that more incident light can be received and a brighter image can be obtained.

(15) The present invention is a camera structure having a cover glass having a laminated structure of the cover glass described in (13) or (14) above, the optical lens group disposed on the cover glass side, the cover glass and the optical There is provided a camera structure comprising an imaging element that receives light incident through a lens group, and an inner transparent plate that is disposed between the optical lens group and the imaging element and transmits light.

According to the invention of the above (15), the camera structure is disposed between the optical lens group and the imaging element, and has an inner transparent plate that transmits light, so that dust attached to the surface of the imaging element can be reduced, resulting As a result, it can exhibit a remarkable effect of improving image quality.

(16) The present invention provides the camera structure according to (15) above, wherein the inner transparent plate is a synthetic resin film.

In many of the small camera modules built into information communication devices such as tablet PCs and smart phones, near-infrared light cut filters are provided that mainly cut the light in the near-infrared region near the optical element group and the imaging element in the optical path of the imaging element. Did. The near-infrared light cut filter needs to have a near-infrared light reflection film that reflects near-infrared light, and a near-infrared light absorption film that absorbs near-infrared light.

Until now, near-infrared light cut filters have often used glass containing phosphate or fluorinated phosphate that absorbs light in the near-infrared region called blue glass, but generally blue glass breaks well and has less dust particles. It has been difficult to produce 200 μm or less in good yield. It is also conceivable to use a synthetic resin film instead of glass. Since the near-infrared reflecting film must form a dielectric multilayer structure by sputtering or the like, it was difficult to form a film having excellent uniformity on the synthetic resin film.

According to the invention of the above (16), since the cover glass can take the near-infrared light reflection function, a synthetic resin film can be used for the inner transparent plate. The synthetic resin film can be made up to a thickness of 100 μm or less, shortening and lengthening the length of the camera structure, and consequently exhibiting a remarkable effect that the thickness of the information communication device that embeds the camera can be made thinner.

(17) The present invention provides the camera structure according to (15) or (16) above, wherein the thickness of the inner transparent plate is 0.2 mm or less.

According to the invention of the above (17), since the thickness of the inner transparent plate is thinner than 0.2 mm, the length of the camera structure can be shortened and thinned, and consequently, the thickness of the information communication device including the camera can be further reduced. Have

(18) The present invention provides the camera structure according to any one of (15) to (17) above, wherein the inner transparent plate is provided with an antireflection layer that prevents reflection of light in at least the visible region.

According to the invention of the above (18), if the anti-reflection layer is provided on the surface of the lens group side of the inner transparent plate, at least an incident light can be received by the anti-reflection function to prevent reflection of light in the visible region, resulting in a brighter image. It has the effect of being acquired. In addition, if an anti-reflection film is provided on the imaging element side of the inner transparent plate, reflected light originating from the inner transparent plate, particularly reflected light from the imaging element itself, is prevented from being reflected back to the inner transparent plate and returning to the imaging element, thereby improving image quality. It shows a remarkable effect to be improved.

(19) The present invention provides the camera structure according to any one of (15) to (17) above, characterized in that an antireflection layer for preventing reflection of light in at least a visible region is provided on both sides of the inner transparent plate.

According to the invention of (19) above, it is possible to receive more incident light, and also to prevent reflected light originating from the inner transparent plate, in particular reflected light from the imaging element itself, from being reflected back to the inner transparent plate and returning to the imaging element. Thus, it exhibits a remarkable effect of improving image quality.

(20) The present invention provides the camera structure according to (18) or (19), characterized in that the anti-reflection layer is a fine protrusion structure formed of fine protrusions formed on the surface of the inner transparent plate.

A micro-protrusion structure made of fine protrusions formed on the surface of the inner transparent plate, an anti-reflection layer of a so-called moth-eye structure, prevents reflection of light over a wide band. Therefore, according to the invention of the above (20), by forming the anti-reflection film having a mos-eye structure, the reflected light caused by the inner transparent plate is significantly reduced over a wide band, thereby exhibiting a remarkable effect of improving the image quality.

(21) The present invention provides the camera structure according to (18) or (19), wherein the anti-reflection layer is a coating film formed on the surface of the inner transparent plate.

A multilayer film in which two types of thin films having different refractive indices are alternately stacked can form an antireflection film for light. And it is known that such a multilayer film can also be obtained by applying a synthetic resin. According to the invention of the above (21), it exhibits a remarkable effect capable of manufacturing an inner transparent plate having an anti-reflection film of stable quality in a low-cost and in large quantity.

(22) The present invention provides the camera structure according to any one of (15) to (21) above, wherein the inner transparent plate further includes a near infrared light absorbing portion that absorbs light in the near infrared region.

According to the invention of the above (22), it is possible to suppress the light in the near-infrared region in a state in which the incident angle dependence of light is small.

(23) The present invention provides the camera structure according to (21) above, wherein the near-infrared light absorbing portion contains an organic dye.

According to the invention of the above (23), it is possible to cut light in the near-infrared region without dependence on the angle of incidence with respect to light absorption without using a blue glass which is generally used as a material for a filter for absorbing light in the near-infrared region. It shows an effect.

(24) The present invention provides an imaging device characterized by having the camera structure described in (15) to (23) above.

According to the invention of the above (24), since the cover glass has a near-infrared light reflecting film that reflects light, it is possible to exhibit an effect of not allowing near-infrared light from outside to enter the internal mechanism of the imaging device. In addition, since it is not necessary to put a member having a near-infrared light reflection film in an area close to the imaging element, reflection of light incident on the internal mechanism of the imaging device can be suppressed, and consequently, stray light is suppressed to prevent ghost or flare. It can exhibit a reducing effect. In addition, since it is disposed between the optical lens group and the imaging element and has an inner transparent plate that transmits light, dust adhering to the surface of the imaging element can be reduced. Therefore, the image quality is improved than in the prior art, and a remarkable effect can be realized at a low cost in an imaging device equipped with a compact camera structure.

ADVANTAGE OF THE INVENTION According to this invention, the cover glass which protects the internal mechanism of an imaging device, especially a camera provided in a portable communication device from external, can cut the light of a near-infrared region, and without a built-in near-infrared cut filter inside a camera, In addition to improving the image quality of the image, it is possible to exhibit remarkable effects such as miniaturization, cost reduction, and simplification of the assembly process.

1A is a cross-sectional view of a camera structure applied to a portable communication device A that is an imaging device according to the first embodiment of the present invention. (B) is a structural diagram of a cover glass having an optical filter function. (C) is a structural diagram of a cover glass having an optical filter function provided with a plurality of antireflection films.
2 (A) is a view showing the dependence of the incident angle of the spectral transmittance on the near-infrared light reflecting film. (B) is an explanatory diagram for explaining the definition of the incident angle.
3 is a view showing the incident angle dependence of spectral transmittance in a cover glass equipped with an optical filter function having a near infrared light absorbing film and a near infrared light reflecting film.
4 is a diagram comparing spectral transmittance of a cover glass having an optical filter function, a glass having a near-infrared light absorbing film, and a glass having a near-infrared light reflecting film.
5 is an explanatory diagram for explaining the spectral transmittance of the dual band cover glass.
6A is a cross-sectional view of the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention. (B) is a structural diagram of a cover glass having an optical filter function. (C) is a structural diagram of the inner transparent plate provided with a plurality of antireflection films using a transparent glass as a base material. (D) is a structural diagram of an inner transparent plate provided with a moseye structure that exhibits antireflection functions on both sides of a transparent synthetic resin film as a base material.
7A is a cross-sectional view of the camera structure applied to the portable communication device A which is the imaging device according to the fourth embodiment of the present invention. (B) is a structural diagram of a cover glass having a near infrared ray reflection function. (C) is a structural diagram of an inner transparent plate provided with a plurality of antireflection films based on transparent glass.
8A is a cross-sectional view of a camera structure applied to a portable communication device A that is an imaging device according to a fifth embodiment of the present invention. (B) is a structural diagram of a cover glass having a near infrared ray reflection function. (C) is a structural diagram of the inner transparent plate having a plurality of anti-reflection films and further comprising a near-infrared light absorbing film.
9A is a cross-sectional view of the camera structure applied to the portable communication device A which is the imaging device according to the sixth embodiment of the present invention. (B) is a structural diagram of a cover glass having a near infrared ray reflection function. (C) is a structural diagram of a plate having a near-infrared light absorption function. (D) is a structural diagram of an inner transparent plate provided with a plurality of antireflection films based on transparent glass.
10A is an explanatory diagram for explaining an experiment method using a conventional camera structure. (B) is a sectional view of a conventional cover glass. (C) is a cross-sectional view of a conventional near infrared light cut filter. (D) is an image captured by a conventional camera structure. (E) is an explanatory diagram for explaining an experiment method using a camera structure according to the present invention. (F) is a cross-sectional view of the cover glass with the optical filter function in the camera structure according to the present invention. (G) is a sectional view of the inner transparent plate in the camera structure according to the present invention. (H) is an image captured by the camera structure according to the present invention.
11A is an explanatory diagram for explaining a conventional camera structure in a portable communication device. (B) is a cross-sectional view of a conventional camera structure in a portable communication device.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 to 10 are examples of embodiments for carrying out the invention, and the same reference numerals in the drawings indicate the same.

1A shows a camera structure applied to the imaging device according to the first embodiment of the present invention. In the case of this embodiment, the imaging device is an information communication device or a portable communication device (A). The camera structure has a cover glass 100 equipped with an optical filter function from the incident side of light, and a camera module 1 accommodated in a case 20 of a portable communication device A such as a smart phone. The camera module 1 is provided through a lens unit 50 which is a group of optical lenses disposed on the side of the cover glass 100 having an optical filter function, and through the cover glass 100 and the lens unit 50 having an optical filter function. It is characterized in that it is provided with an imaging element (70) for receiving the incident light, and a near-infrared light cut filter for cutting light in the near-infrared region is not disposed between the optical paths from the lens unit (50) to the imaging element (70). Doing. Specifically, as shown in (A) of FIG. 1, the cover glass 100 having an optical filter function, the lens unit 50, the lens carrier 40, the magnet holder 30, the imaging element 70, and It is mainly composed of the substrate 80, and is fixed to the smart phone case 20. The connection between the imaging element 70 and the substrate 80 may be connected by wire bonding, or flip chip mounting may be performed.

What is significantly different from the conventional camera structure of Fig. 11B is that the optical filter 60 for cutting near-infrared light (refer to Fig. 11B) that is necessary for improving the conventional image quality is omitted. Instead, a filter function for cutting light in the near-infrared region was added to the cover glass 10, which conventionally played a role of protecting the camera module 1. By setting it as such a structure, since the length D2 of the whole camera structure is made shorter than the conventional D1 (refer FIG. 11 (B)), and since the optical filter 60 is not arrange | positioned near the imaging element 70, an optical filter In the manufacturing process of (60), the particulate matter (particles) attached to the filter surface falls to the surface of the imaging element 70, thereby exhibiting a remarkable effect of eliminating the problem of deteriorating the image. Further, in the assembly process of the camera module 1, there is no need for a process for arranging and assembling the near-infrared light cut filter 60, further contributing to cost reduction, yield improvement, and work efficiency.

In addition, by providing the camera structure of Fig. 1A, the portable communication device A is more compact, thinner, and cheaper to produce.

Fig. 1 (B) shows a laminated structure of a cover glass 100 that is continuously installed in the case of the portable communication device A and is provided with an optical filter function to protect the camera module, which is an internal mechanism, from outside. The cover glass 100 having an optical filter function uses the crystallized glass 130 as a transparent substrate that transmits light, and reflects the light in the ultraviolet region and further suppresses the reflection of light in the visible region 120 Based on the crystallized glass 130, it is formed on the incident side of light. Also, on the outermost side of the side where light is incident, an antifouling coating film 110 is provided to prevent contamination from outside. A near-infrared light reflecting film 150 that reflects light in the near-infrared region, in turn, from the farthest side based on the crystallized glass 130 on the light exit side, and a near-infrared light absorbing film 140 that absorbs light in the near-infrared region ) Is formed. An anti-reflection film 120 may be further formed on the farthest side of the light exit side (see FIG. 1C).

In general, crystallized glass has large crystal grains, making it difficult to pass light. However, with recent advances in technology, it is possible to control crystal grains to nanometer size, such as impact-resistant and high-hardness clear glass ceramics manufactured by Ohara Co., Ltd., thereby increasing light transmittance (Ohara Co., Ltd., [online], new information) ＞ Information on release of impact-resistant and high-hardness clear glass ceramics (press release delivery), [February 9, 2016 search], Internet (URL: http://www.ohara-inc.co.jp/jp/news/dl /pressrelease151216.pdf)). When such a crystallized glass is used, a cover glass having both impact resistance and fracture toughness, which is difficult to crack, can be produced. And by forming the laminated structure on the cover glass, the cover glass 100 having an optical filter function is realized. The use of blue glass as the cover glass 100 provided with the optical filter function is also conceivable in theory, but it is not suitable because it has low impact resistance and lacks fracture toughness that is difficult to crack. It is also conceivable to form a cover glass 100 having an optical filter function by depositing a near-infrared light absorbing film 140 or a near-infrared light reflecting film 150, which will be described later, on the tempered glass, when the crystallized glass 130 is used. Compared with this, it has a defect that has low impact resistance. In addition, it is conceivable to form a near-infrared light absorbing film 140 or a near-infrared light reflecting film 150 on a sapphire glass having a high hardness, thereby forming a cover glass 100 equipped with an optical filter function. Compared to the case where the crystallized glass 130 is used, workability is low.

The antifouling coating film 110 prevents fingerprint contamination and sebum contamination, and facilitates wiping off the contamination. The antifouling coating film 110 is formed of a fluorine-based coating agent or the like, and is formed on the outermost side of the incident side of light in the laminated structure of the cover glass by application or spraying.

The anti-reflection film 120 reflects light in the ultraviolet region and suppresses reflection of light in the visible region. The antireflection film 120 is a dielectric multilayer film, and is also formed by alternately laminating a nitride film and an oxide film. The dielectric film constituting the antireflection film 120 is formed by alternately laminating a plurality of nitride films and oxide films. As the nitride film, silicon nitride, silicon oxynitride, aluminum nitride, or the like can be used. When using silicon oxynitride, it is preferable that the stoichiometric ratio (oxygen / nitrogen) of oxygen and nitrogen is 1 or less. As the oxide film, silicon oxide (SiO ₂ ), aluminum oxide (Al ₂ O ₃ ), or the like can be used. By using silicon nitride or silicon oxynitride as the film of the anti-reflection film 120, the anti-reflection film 120 can be formed using the same film-forming method and film-forming apparatus as the near-infrared light reflective film 150, which will be described later. It is advantageous.

The anti-reflection film 120 may use an oxide film instead of a nitride film. In addition to silicon oxide, the material of the oxide film is titanium oxide (TiO ₂ ), aluminum oxide (Al ₂ O ₃ ), zirconium oxide (ZrO ₂ ), tantalum oxide (Ta ₂ O ₅ ), niobium oxide (Nb ₂ O ₅₎ ) And the like. When the antireflection film 120 is composed of a plurality of types of oxide films having different refractive indices, the oxide is appropriately selected.

The anti-reflection film 120 may use a known film forming method, such as a vacuum deposition method, sputtering method, ion beam assisted deposition method (IAD method), ion plating method (IP method), ion beam sputtering method (IBS method), or the like. It is preferable to use a sputtering method or an ion beam sputtering method for forming the nitride film.

The near-infrared light absorbing film 140 is formed on the side of the crystallized glass 130 opposite to the anti-reflection film 120 described above, that is, on the imaging element 70 side of the cover glass 100 having an optical filter function. The near-infrared light absorbing film 140 transmits light in the visible region and absorbs a part of the light in the near-infrared region from the red region. The near-infrared light absorption film 140 includes an organic dye, and is composed of a resin film having a maximum absorption wavelength in a range of 650 nm to 750 nm (see broken line in FIG. 4). Since the near-infrared light absorbing film 140 is adjacent to the crystallized glass 130, it is preferable to decrease the reflectance at the interface by reducing the difference in refractive index between the two. By having such a near-infrared light absorbing film 140, it is possible to reduce the dependence of the spectral transmittance characteristic by the angle of incidence and have excellent near-infrared light cutability.

As the organic dye, an azo-based compound, a phthalocyanine-based compound, a cyanine-based compound, or a dimonium-based compound can be used. As the resin material as a binder (a color binder) constituting the near-infrared light absorbing film 140, polyacrylic, polyester, polycarbonate, polystyrene, polyolefin, or the like can be used. The resin material may be a mixture of a plurality of resins, or may be a copolymer using a monomer of the resin. In addition, the resin material may be one having a high transmittance with respect to light in the visible region, and is selected in consideration of compatibility with an organic dye, a film forming process, and cost. Further, in order to improve the ultraviolet resistance of the near-infrared light-absorbing film 140, it is also possible to add a quencher (quenching dye) such as a sulfur compound to the resin material.

For the formation of the near-infrared light absorbing film 140, for example, the following method can be used. First, the resin binder is dissolved with a known solvent such as methyl ethyl ketone or toluene, and the above-described organic dye is added to prepare a coating solution. Subsequently, the coating solution is applied to the crystallized glass 130 by a spin coating method, for example, and dried and cured in a drying furnace.

The near-infrared reflecting film 150 is a dielectric multilayer film formed by alternately stacking a plurality of dielectrics having different refractive indices like the anti-reflection film 120. However, the dielectric multilayer film constituting the near-infrared light reflection film 150 is formed by stacking a plurality of types of oxide films having different refractive indices, and the adjacent oxide films are different types of oxide films. In the first embodiment, the near-infrared light reflection film 150 is formed by alternately stacking dozens of layers of two types of oxide films. In addition to silicon oxide, titanium oxide (TiO ₂ ), aluminum oxide (Al ₂ O ₃ ), zirconium oxide (ZrO ₂ ), tantalum oxide (Ta ₂ O ₅ ), niobium oxide (Nb ₂ O ₅ ), etc. are used as the oxide film. .

In the near-infrared light reflection film 150, the film thickness of each oxide film is formed to a thickness of λ / 4 with the wavelength of the light to be reflected as λ. By doing so, the light reflected from all the interfaces of the alternating layer becomes the same phase when it reaches the incident surface, and results in the light being strengthened, that is, the reflectance increases near the wavelength lambda and functions as a light reflecting film. In this embodiment, the film may be designed to reflect light in the near infrared region as λ. In addition, the near-infrared light reflection film 150 is also formed using a film forming method and a film forming apparatus similar to the antireflection film 120 described above.

The human eye is sensitive to so-called visible light with a wavelength of 380 nm to 780 nm. On the other hand, the imaging element generally includes visible light and has sensitivity to long wavelength light, that is, light having a wavelength of about 1.1 μm. Therefore, if the image captured by the imaging element is taken as a photograph, it is not visible in a natural color tone and causes discomfort.

When the cover glass 100 equipped with the optical filter function has a stacked structure as shown in FIG. 1 (B) or FIG. 1 (C), since the near infrared light reflecting film 150 by the dielectric multilayer film is provided, the near infrared light It is possible to cut light having a wavelength of 700 nm or more that cannot be absorbed by the absorbing film 140, and to acquire an image with a natural color tone. In addition, when attempting to cut the light in the near-infrared region using only the near-infrared light reflecting film 150, the reflectance varies greatly depending on the incident angle of the incident light, as will be described later. By combining the near-infrared light reflecting film 150 and the near-infrared light-absorbing film 140 that does not have an incident angle dependence on the light absorption rate, it is possible to construct a near-infrared light cut filter in which light transmittance is less dependent on the incident angle of light. .

In addition, since the cover glass 100 protecting the camera in the smart phone case 20 from the outside can cut the light in the ultraviolet region by the anti-reflection film 120, a group of optical lenses formed of synthetic resin as a component of the camera (Lens unit 50) can be prevented from being deteriorated by ultraviolet rays, and it is also possible to prevent the near-infrared light absorption film 140 containing an organic dye from being degraded by ultraviolet rays. In addition, the anti-reflection function of light in the visible region allows more incident light to be received and a bright image to be obtained.

The anti-reflection film 120 is formed by alternately laminating a nitride film and an oxide film. In general, the nitride film has a higher hardness than an oxide film and reaches a hardness of 9H or more in a pencil hardness test. Therefore, by forming the anti-reflection film 120 including a nitride film, it exhibits an effect of increasing scratch resistance. In addition, the nitride film has a higher packing density and a higher density than the oxide film. Since it does not contain oxygen as a component, it is not an oxygen source. Therefore, by providing the nitride film on the outside of the near-infrared light absorbing film 140, it is possible to prevent oxygen and moisture from entering the near-infrared light absorbing film 140, and suppress the deterioration of the near-infrared absorbing film 140.

In general, optical filters have multiple optical interfaces. Meanwhile, the lens is provided with a highly antireflection film. It is difficult to achieve the same level of transmittance as that of a lens with an optical filter that cuts light in the near-infrared region, so that reflection light is returned to the lens side. This causes stray light to cause ghosts in the image. In the conventional camera structure, since the optical filter 60 is placed next to the imaging element 70 on the optical path between the lens unit 50 and the imaging element 70, it is difficult to avoid the occurrence of such ghost. However, according to the camera structure according to the present embodiment, since stray light as described above is not generated, a remarkable effect of improving image quality is exhibited.

Next, the spectral transmittance characteristics of the cover glass 100 having an optical filter function will be described.

FIG. 2 (A) shows experimental results on how the spectral transmittance characteristics of the near-infrared reflecting film formed by the dielectric film depend on the incident angle of light. The incident angle A is defined as in Fig. 2B. In addition, "T" on the vertical axis represents spectral transmittance, and the unit is% (percent). In addition, "λ" on the abscissa represents the wavelength of light, and the unit is nm (nanometer) (same in the drawings below). In the sample, 40 layers of titanium dioxide (TiO ₂ ) and silicon dioxide (SiO ₂ ) were alternately stacked in a predetermined film thickness on glass. When the solid line has a light incident angle of 0 °, the dashed line shows the spectral transmittance when the light has a light incident angle of 30 °. It was confirmed from FIG. 2 that a significant difference in spectral transmittance occurred at light incidence angles of 0 ° and 30 ° for light near the wavelength of 700 nm in the red region. If there is such a difference, the color tone of the image is greatly changed at the center and periphery of the image, resulting in deterioration of the final image quality.

3 shows experimental results on how the spectral transmittance of the cover glass 100 with the optical filter function according to the present embodiment having both the near-infrared light absorbing film and the near-infrared reflecting film depends on the incident angle of light. As the near-infrared light absorbing film, a resin film having a thickness of 5 µm or less containing an organic dye is used, and as the near-infrared reflecting film, the structure is the same as in FIG. 2. When the solid line has a light incident angle of 0 °, the dashed line has a light incident angle of 15 °, and the dashed-dotted line shows the spectral transmittance when the light has a light incident angle of 30 °. It can be seen that the dependence of the incident angle is smaller than in the case of FIG. 2.

4 shows a cover glass 100 (solid line) having an optical filter function having a near-infrared light absorption film 140 and a near-infrared light reflection film 150 and a cover glass (dashed line) formed only of the near-infrared light absorption film 140 ) Is a diagram comparing the experimental results in the measurement of the spectral transmittance of the cover glass (single-dot chain line) formed only with the near-infrared reflecting film 150. The structures of the near-infrared light absorbing film 140 and the near-infrared light reflecting film 150 are the same as those of FIGS. 2 and 3, and thus descriptions thereof are omitted. However, the incident angle of all light is 0 °. In the case of the near-infrared light absorption film 140 alone, strong light absorption is performed for light of 650 to 750 nm, but light of 800 nm or more is mostly transmitted. As described above, since the human eye is mainly sensitive to so-called visible light having a wavelength of 380 nm to 780 nm, when the imaging element 70 is imaged to a region having a sensitivity of 800 nm or more, an unnatural image to the human eye as described above It becomes. The near-infrared reflecting film 150 is designed to cut for light having a wavelength of 700 nm or more, and in fact, a sharp decrease in spectral transmittance is measured around 700 nm. A combination of the near-infrared light absorbing film 140 and the near-infrared light reflecting film 150 is a cover glass 100 having an optical filter function, and as illustrated by a solid line in FIG. 4, 400 to 650 nm of visible light As for, it can be confirmed that a high transmittance is realized, and light having a wavelength of 700 nm or more is cut.

5 is a view showing the spectral transmittance of a cover glass having an optical filter function of a camera structure according to a second embodiment of the present invention. In this embodiment, a cover glass and a camera structure provided with a so-called dual band optical filter function capable of acquiring images even at night. The basic structure of the camera structure is the same as that of the first embodiment, but the cover glass 100 having an optical filter function includes a near-infrared light reflecting film D having a high light transmittance for a portion of light in the near-infrared region. Since the film structure of the near-infrared reflecting film (D) is a known technique, the description is omitted.

Combining the near-infrared light absorbing film 140 indicated by the broken line in FIG. 5 with a part of the light in the near-infrared region indicated by the dashed-dotted line in FIG. 5 combines the near-infrared reflective film D with a high light transmittance, and the solid line in FIG. Similarly, a dual band cover glass that transmits a portion of light in the visible region and light in the near-infrared region can be realized. However, in FIG. 5, the spectral transmittance of the near-infrared light reflecting film D and the dual band cover glass is calculated at a wavelength of 750 nm or more. According to the camera structure equipped with such a dual band cover glass, it is possible to obtain a remarkable effect that a lane boundary line or a roadway outside line is easily seen on a road at night, which is very suitable for a vehicle camera.

6A is a cross-sectional view of the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention. The camera structure includes a cover glass 210 having an optical filter function that protects the internal mechanism of the imaging device from the outside, and a camera module 1. The camera module 1 includes an optical lens group that is an internal mechanism of an imaging device, that is, a lens unit 50, a lens carrier 40 holding the lens unit 50, and a lens unit 50 to realize an autofocus function. ) The magnet holder 30 for moving in the axial direction, the cover glass 210 with an optical filter function, and the imaging element 70 for receiving light incident through the lens unit 50, and the lens unit 50 ), And an inner transparent plate 240 which is disposed between the imaging elements 70 and is based on a transparent glass that transmits light. The inner transparent plate 240 has a thin plate structure, and covers at least a portion of the surface of the imaging element 70 when the imaging element 70 is viewed from the lens unit 50 side in the axial direction.

6B is a structural diagram of the cover glass 210 having an optical filter function. The cover glass 210 provided with the optical filter function uses the crystallization glass 130 as a transparent substrate that transmits light, reflects light in the ultraviolet region, and also prevents reflection of light in the visible region 120 Based on the crystallized glass 130, it is formed on the incident side of light. In addition, on the outermost side of the side where light is incident, an antifouling coating film 110 is provided to prevent contamination from outside. On the light exit side, the near-infrared light reflecting film 150 that reflects light in the near-infrared region and the near-infrared light absorbing film 140 that absorbs light in the near-infrared region, in turn, from the farthest side based on the crystallized glass 130 It is formed. An antireflection film 120 may be further formed on the farthest side of the light exit side (see FIG. 1C).

That is, the cover glass 210 having an optical filter function is a laminated structure of a cover glass that protects the internal mechanism of the imaging device from the outside, and crystallized glass 130 which is a transparent substrate that transmits light and light in the near infrared region It has a laminated structure of a cover glass, characterized in that it comprises a near-infrared reflecting film 150 for reflecting. In addition, the cover glass 210 having an optical filter function further includes an antireflection film 120 that reflects light in the ultraviolet region and also prevents reflection of light in at least the visible region.

In addition, the cover glass 210 having an optical filter function includes a near infrared light absorbing film 140 that absorbs light in the near infrared region, and the near infrared light absorbing film 140 includes an organic dye.

The camera structure applied to the portable communication device A, which is an imaging device according to the third embodiment of the present invention, includes a cover glass 210 having the optical filter function, and a cover glass 210 having an optical filter function. ) An optical lens group (lens unit 50) disposed on the side, a cover glass 210 having an optical filter function, and an imaging element 70 that receives light incident through the lens unit 50, and a lens It is disposed between the unit 50 and the imaging element 70 and includes an inner transparent plate 240 that transmits light.

The manufacturing method of the near-infrared reflective film 150, the near-infrared absorbing film 140, and the anti-reflection film 120 is the same as in the first embodiment, and thus description thereof is omitted.

6C is a structural diagram of the inner transparent plate 240 provided with a plurality of anti-reflection films based on the transparent glass 220. The inner transparent plate 240 includes anti-reflection layers 230 that prevent reflection of light in at least a visible region on both surfaces of the transparent glass 220. The antireflection layer 230 is prepared in the same way as the antireflection film 120.

That is, the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention is a laminated structure of a cover glass that protects the internal mechanism of the imaging device from the outside, and is a transparent substrate that transmits light. Crystallized glass 130, a near-infrared light reflection film 150 for reflecting light in the near-infrared region, an anti-reflection film 120 for reflecting light in the ultraviolet region and preventing reflection of light in at least the visible region, and near-infrared A cover glass 210 having an optical filter function having a near-infrared light absorbing film 140 for absorbing light in a region, an optical lens group disposed on the side of the cover glass 210 having an optical filter function, and optical A cover glass 210 having a filter function and an imaging element 70 for receiving light incident through the optical lens group, and a transparent glass disposed between the optical lens group and the imaging element 70 and transmitting light ( 220) A camera structure comprising the transparent plate 240.

According to the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention, the cover glass 210 having an optical filter function has a near-infrared reflecting film 150 that reflects light. Therefore, it is possible to exhibit an effect of not allowing near-infrared light from outside to enter the internal mechanism of the imaging device. In addition, since it is not necessary to put a member having the near-infrared light reflection film 150 into the region close to the imaging element 70, reflection of light incident on the internal mechanism of the imaging device can be suppressed, and consequently, stray light is suppressed. It can have a remarkable effect of reducing the cause of ghosts or flares.

According to the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention, the cover glass 210 having an optical filter function that protects the internal mechanism of the imaging device from the outside is an ultraviolet region. Since it can cut the light of, the optical lens or the like formed of synthetic resin, which is a component of the camera, can be prevented from being deteriorated by ultraviolet rays, contributing to a longer life. In addition, it is said that the cover glass 210 equipped with the optical filter function has an anti-reflection film 120 that prevents reflection of light in at least a visible region, so that more incident light can be received and a brighter image can be obtained. It has a remarkable effect.

According to the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention, near infrared light is applied to the near infrared light absorbing film 140 formed on the cover glass 210 having an optical filter function. Since it contains an organic dye that absorbs, it is possible to suppress light in the near-infrared region in a state where there is little dependence on the angle of incidence of light, without using blue glass, which is generally used as a filter material for absorbing light in the near-infrared region. It shows an effect.

According to the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention, the camera structure is disposed between the optical lens group and the imaging element 70 and transmits light inside the transparent plate Since it is provided with 240, the dust adhering to the surface of an imaging element can be reduced, and as a result, the remarkable effect of improving image quality can be exhibited.

According to the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention, an anti-reflection layer 230 that prevents reflection of light in at least a visible region on both sides of the inner transparent plate 240 is provided. Since it is provided, it is possible to receive more incident light, and reflected light originating from the inner transparent plate 240, in particular reflected light from the imaging element 70 itself, is reflected back to the inner transparent plate 240, and the imaging element 70 ), And exhibits a remarkable effect of improving image quality.

In addition, since the specific structure and manufacturing method of the near-infrared reflective film 150, the near-infrared absorbing film 140, the anti-reflective film 120, and the anti-reflective layer 230 are the same as those in the first embodiment, the description is omitted.

6 (D) is a camera structure applied to a portable communication device (A) that is an imaging device according to the third embodiment, in which an inner transparent plate 240 based on transparent glass is described and a transparent synthetic resin film is described. It is part of a modified embodiment, which is replaced by an inner transparent plate 242. That is, it is a structural diagram of the inner transparent plate 242 based on the transparent synthetic resin film provided with the mos-eye structure which exhibits the anti-reflection function on both sides using the transparent synthetic resin film 222 as the substrate. The thickness of the inner transparent plate 242 based on the transparent synthetic resin film is 0.2 mm or less. The inner transparent plate 242 based on a transparent synthetic resin film has a moth-eye structure 232 on both surfaces to prevent reflection of light in at least a visible region.

The mos-eye structure does not reduce reflection using an interference effect like a dielectric multi-layer film, but reduces reflection by excluding the interface where the refractive index changes rapidly. Specifically, a fine protrusion structure formed of a plurality of fine protrusions having a height on the order of several hundreds of nm is formed on the surface, and the repetition period of the protrusions is related to a wavelength range in which reflection reduction effect is exhibited. Since the description is omitted because it is a well-known technique for the moth-eye structure, in the case of this modified embodiment, for example, a transparent acrylic resin is used as the transparent synthetic resin film 222, and reflection is prevented by forming the mos-eye structure by transfer or molding. Realize the function.

That is, the fine protrusion structure made of fine protrusions formed on the surface of the inner transparent plate 242 based on the transparent synthetic resin film, the so-called anti-reflection film 232 of the mos-eye structure prevents reflection of light over a wide band. The moth-eye structure 232 preferably has an anti-reflection function for light in the visible region, and an anti-reflection function for light in the ultraviolet region and light in the near-infrared region.

In addition, as another modified example of the inner transparent plate 240, it is also conceivable to form a multilayer film obtained by applying a synthetic resin as an antireflection layer on the surface of the transparent synthetic resin film 222 as a base material. In general, a multilayer film obtained by alternately laminating two types of thin films having different refractive indices of light can form an antireflection film for light. And it is known that such a multilayer film can also be obtained by application of a synthetic resin.

For example, as two types of synthetic resins having different refractive indices of light, those having both refractive indices greater than the refractive index of air and smaller than the refractive indices of the transparent synthetic resin film 222 are prepared. By coating these alternately on the transparent synthetic resin film 222, it is possible to manufacture the inner transparent plate 240 with an antireflection film of stable quality at low cost. As a method of applying the synthetic resin to the transparent synthetic resin film 222, for example, a roller coating method or the like can be considered. According to this modified example, the inner transparent plate provided with the antireflection film has a remarkable effect that it can be manufactured in a stable quality, in large quantities, and inexpensively.

According to the camera structure applied to the portable communication device A which is the imaging device according to the third embodiment of the present invention, the anti-reflection film having a mos-eye structure on both sides of the inner transparent plate 242 based on a transparent synthetic resin film ( By forming 232), reflected light originating from the inner transparent plate 242 based on the transparent synthetic resin film is significantly reduced over a wide band including the visible light region, thereby exhibiting a remarkable effect of improving image quality.

7A is a cross-sectional view of the camera structure applied to the portable communication device A which is the imaging device according to the fourth embodiment of the present invention. This camera structure includes a cover glass 215 having a near-infrared light reflection function that reflects near-infrared light, and an inner transparent plate 240 based on transparent glass. Other configurations are the same as those of the third embodiment described above, and thus description thereof is omitted.

7B is a structural diagram of the cover glass 215 having a near-infrared light reflection function. The cover glass 215 having a near-infrared light reflection function uses a crystallized glass 130 as a transparent substrate that transmits light, reflects light in the ultraviolet region, and also prevents reflection of light in the visible region 120 ) Is formed on the incident side of light based on the crystallized glass 130. In addition, an antifouling coating film 110 is provided on the outermost side of the side where light is incident to prevent contamination from the outside. Based on the crystallized glass 130, a near-infrared light reflection film 150 that reflects light in the near-infrared region is formed on the light emission side. An anti-reflection film 120 may be further formed on the farthest side of the light exit side (see FIG. 1C).

7C is a structural diagram of the inner transparent plate 240 provided with a plurality of anti-reflection layers 230 based on the transparent glass 220. The inner transparent plate 240 includes anti-reflection layers 230 on both sides of the transparent glass 220.

That is, the camera structure applied to the portable communication device A which is the imaging device according to the fourth embodiment of the present invention is a laminated structure of a cover glass that protects the internal mechanism of the imaging device from the outside, and is a transparent substrate that transmits light. Near-infrared comprising a crystallized glass 130, a near-infrared light reflecting film 150 that reflects light in the near-infrared region, and an anti-reflection film 120 that reflects light in the ultraviolet region and prevents reflection of light in at least the visible region A cover glass 215 having an external light reflection function, an optical lens group disposed on the cover glass 215 side having a near infrared light reflection function, and a cover glass 215 and optical lens group having a near infrared light reflection function It has an imaging element 70 for receiving light incident through, and an inner transparent plate 240 based on a transparent glass 220 which is disposed between the optical lens group and the imaging element 70 and transmits light. That A camera structure as.

The inner transparent plate 240 based on the transparent glass 220 may be replaced with the inner transparent plate 242 based on the transparent synthetic resin film (see FIG. 6D).

According to the camera structure applied to the portable communication device A which is the imaging device according to the fourth embodiment of the present invention, the near-infrared light reflecting film 150 in which the cover glass 215 having the near-infrared light reflection function reflects light is reflected. Therefore, it is possible to exhibit an effect of not allowing near-infrared light from outside to enter the internal mechanism of the imaging device. In addition, since it is not necessary to put a member having the near-infrared light reflection film 150 in an area close to the imaging element 70, reflection of light incident on the internal mechanism of the imaging device can be suppressed, and consequently stray light is suppressed. It can have a remarkable effect of reducing the cause of ghosts or flares.

According to the camera structure applied to the portable communication device A which is the imaging device according to the fourth embodiment of the present invention, the cover glass 215 having a near-infrared light reflection function that protects the internal mechanism of the imaging device from the outside is ultraviolet. Since the light in the region can be cut, optical lenses or the like formed of synthetic resin, which is a component of the camera, can be prevented from being deteriorated by ultraviolet rays, contributing to long life. In addition, the cover glass 215 having a near-infrared light reflection function has at least an anti-reflection film 120 that prevents reflection of light in the visible region, so that more incident light can be received and a brighter image can be obtained. It has a remarkable effect.

According to the camera structure applied to the portable communication device A which is the imaging device according to the fourth embodiment of the present invention, the camera structure is disposed between the optical lens group and the imaging element 70 and transmits light inside. Since the plate 240 is provided, dust adhering to the surface of the imaging element can be reduced, and as a result, a remarkable effect of improving image quality can be exhibited.

According to the camera structure applied to the portable communication device A which is the imaging device according to the fourth embodiment of the present invention, on both sides of the inner transparent plate 240, at least the antireflection layer 230 that prevents reflection of light in the visible region Since it is provided, it is possible to receive more incident light, and further, reflected light originating from the inner transparent plate 240, particularly reflected light from the imaging element 70 itself, is reflected back to the inner transparent plate 240 to image the imaging element. It prevents returning to (70) and exhibits a remarkable effect of improving image quality.

8A is a cross-sectional view of a camera structure applied to a portable communication device A that is an imaging device according to a fifth embodiment of the present invention. This camera structure includes a cover glass 215 having a near-infrared light reflection function that reflects near-infrared light, and an inner transparent plate 244 having a near-infrared light absorption function based on transparent glass. Other configurations are the same as those of the third embodiment described above, and thus description thereof is omitted.

8B is a structural diagram of a cover glass 215 having a near-infrared light reflection function. The cover glass 215 having a near-infrared light reflection function uses a crystallized glass 130 as a transparent substrate that transmits light, reflects light in the ultraviolet region, and also prevents reflection of light in the visible region 120 ) Is formed on the incident side of light based on the crystallized glass 130. In addition, an antifouling coating film 110 is provided on the outermost side of the side to which light is incident to prevent contamination from outside. Based on the crystallized glass 130, a near-infrared light reflection film 150 that reflects light in the near-infrared region is formed on the light emission side. An anti-reflection film 120 may be further formed on the farthest side of the light exit side (see FIG. 1C).

FIG. 8 (C) is provided with a plurality of anti-reflection layers 230 that prevent reflection of light in at least a visible region, and an inner transparent having a near-infrared absorption function further comprising a near-infrared absorption film 140 that is a near-infrared absorption unit. It is a structural diagram of the plate 244. The inner transparent plate 244 having the near-infrared light absorbing function is based on the transparent glass 220, and the near-infrared light absorbing film 140 is provided on the transparent glass 220.

The anti-reflection layer 230 is formed on the incident side of the light with respect to the transparent glass 220, and in turn, the anti-reflection layer 230 and the root on the output side of the light from the farthest side with respect to the transparent glass 220 The external light absorbing film 140 is provided. The near-infrared light absorbing film 140 includes an organic pigment

The specific structure and manufacturing method of the near-infrared reflective film 150, the near-infrared absorbing film 140, the anti-reflective film 120, and the anti-reflective layer 230 are the same as those in the first embodiment, and thus description thereof is omitted.

In addition, the inner transparent plate 244 having a near-infrared light absorption function may be replaced with a similar one to the inner transparent plate 242 based on a transparent synthetic resin film (see FIG. 6 (D)). However, at this time, it is preferable to provide a near-infrared light absorbing film 140 adjacent to the transparent synthetic resin film 222. In other words, the anti-reflection layer, the moss-eye structure 232 is formed on the light incident side with respect to the transparent synthetic resin film 222, and in turn, the moss eye from the farthest side based on the transparent synthetic resin film 222 on the light exit side. It is preferable that the structure 232 and the near-infrared light absorbing film 140 are provided.

As a means for realizing the inner transparent plate 244 having a near-infrared light absorption function, a thin plate of synthetic resin containing, for example, at least a portion of an organic dye absorbing light in the near-infrared region may be used as a base material. In addition, similar to the conventional near-infrared light cut filter, a so-called blue glass plate that absorbs light in the near-infrared region can also be used. It is also conceivable to attach a film for cutting near-infrared light to a transparent plate and realize it.

According to the camera structure applied to the portable communication device A which is the imaging device according to the fifth embodiment of the present invention, the near-infrared reflecting film 150 in which the cover glass 215 having the near-infrared light reflecting function reflects light is reflected. Therefore, it is possible to exhibit an effect of not allowing near-infrared light from outside to enter the internal mechanism of the imaging device. In addition, since it is not necessary to put a member having the near-infrared light reflection film 150 into the region close to the imaging element 70, reflection of light incident on the internal mechanism of the imaging device can be suppressed, and consequently, stray light is suppressed. It can have a remarkable effect of reducing the cause of ghosts or flares.

According to the camera structure applied to the portable communication device A which is the imaging device according to the fifth embodiment of the present invention, the cover glass 215 having a near-infrared light reflection function that protects the internal mechanism of the imaging device from the outside is ultraviolet. Since the light in the region can be cut, deterioration due to ultraviolet rays, such as an optical lens formed of synthetic resin, which is a component of the camera, can be prevented, contributing to long life. In addition, the cover glass 215 having a near-infrared light reflection function has at least an anti-reflection film 120 that prevents reflection of light in the visible region, whereby more incident light can be received and a brighter image can be obtained. It has a remarkable effect.

According to the camera structure applied to the portable communication device A which is the imaging device according to the fifth embodiment of the present invention, the near infrared light absorbing film 140 formed on the inner transparent plate 244 having the near infrared light absorbing function Since it contains an organic dye that absorbs near-infrared light, it is possible to cut light in the near-infrared region without dependence on the angle of incidence to light absorption without using blue glass, which is generally used as a material for filters for absorbing light in the near-infrared region. Shows the effect.

According to the camera structure applied to the portable communication device A which is the imaging device according to the fifth embodiment of the present invention, reflection of light in at least a visible region is prevented on both sides of the inner transparent plate 244 having a near infrared light absorption function. Since the anti-reflection layer 230 is provided, it is possible to receive more incident light. In addition, reflected light originating from the inner transparent plate 244 having a near-infrared light absorbing function, in particular reflected light from the imaging element 70 itself, is reflected back to the inner transparent plate 244 having a near-infrared light absorbing function, and thus an imaging element Since it can be prevented from returning to (70), it exhibits a remarkable effect of improving the image quality.

9A is a cross-sectional view of a camera structure applied to a portable communication device A that is an imaging device according to a sixth embodiment of the present invention. This camera structure comprises a cover glass 215 having a near-infrared light reflection function for reflecting near-infrared light, a plate 217 with a near-infrared light absorption function for absorbing near-infrared light, and a transparent glass in turn from the incident side of light. An inner transparent plate 240 is used as a base material. Other configurations are the same as those of the third embodiment described above, and thus description thereof is omitted.

9B is a structural diagram of the cover glass 215 having a near-infrared light reflection function. The cover glass 215 having a near-infrared light reflection function uses a crystallized glass 130 as a transparent substrate that transmits light, reflects light in the ultraviolet region, and also prevents reflection of light in the visible region 120 ) Is formed on the incident side of light based on the crystallized glass 130. In addition, an antifouling coating film 110 is provided on the outermost side of the side where light is incident to prevent contamination from the outside. A near-infrared light reflecting film 150 that reflects light in the near-infrared region is formed on the emission side of light based on the crystallized glass 130. An anti-reflection film 120 may be further formed on the farthest side of the light exit side (see FIG. 1C).

9C is a structural diagram of a plate 217 having a near-infrared light absorption function. The plate 217 having the near-infrared light absorbing function has a thin plate-like structure, has a plurality of anti-reflective layers 230 that prevent reflection of light in at least a visible region, and further includes a near-infrared light absorbing film 140. The plate 217 having the absorbing function is based on the transparent glass 220, and the near infrared light absorbing film 140 is provided adjacent to the transparent glass 220. The antireflection layer 230 is formed on the incidence side of the light based on the transparent glass 220, and the antireflection layer 230 and the near-infrared light in turn from the farthest side based on the transparent glass 220 on the light exit side are formed. The absorbent film 140 is provided.

The plate 217 with the near infrared light absorption function is disposed on the inner structure side than the cover glass 215 with the near infrared light reflection function.

As a means for realizing the plate 217 with the near-infrared light absorption function, a thin plate of synthetic resin containing, for example, at least a portion of an organic dye absorbing light in the near-infrared region may be used as a substrate. In addition, similar to the conventional near-infrared light cut filter, a so-called blue glass plate that absorbs light in the near-infrared region can also be used. It is also conceivable to attach a film for cutting near-infrared light to a transparent plate and realize it.

9D is a structural diagram of the inner transparent plate 240 provided with a plurality of anti-reflection layers 230 based on the transparent glass 220. The inner transparent plate 240 includes anti-reflection layers 230 on both sides of the transparent glass 220.

The inner transparent plate 240 based on the transparent glass 220 may be replaced with the inner transparent plate 242 based on the transparent synthetic resin film (see FIG. 6 (D)).

According to the camera structure applied to the portable communication device A which is the imaging device according to the sixth embodiment of the present invention, the near-infrared light reflection film 150 in which the cover glass 215 with the near-infrared light reflection function reflects light is reflected. Therefore, it is possible to exhibit an effect of not allowing near-infrared light from outside to enter the internal mechanism of the imaging device. In addition, since it is not necessary to put a member having the near-infrared light reflection film 150 in an area close to the imaging element 70, reflection of light incident on the internal mechanism of the imaging device can be suppressed, and consequently stray light is suppressed. It can have a remarkable effect of reducing the cause of ghosts or flares.

According to the camera structure applied to the portable communication device A which is the imaging device according to the sixth embodiment of the present invention, the cover glass 215 having a near-infrared light reflection function that protects the internal mechanism of the imaging device from the outside is ultraviolet. Since the light in the region can be cut, deterioration due to ultraviolet rays, such as an optical lens formed of synthetic resin, which is a component of the camera, can be prevented, contributing to long life. In addition, the cover glass 215 having a near-infrared light reflection function has at least an anti-reflection film 120 that prevents reflection of light in the visible region, whereby more incident light can be received and a brighter image can be obtained. It has a remarkable effect.

According to the camera structure applied to the portable communication device A which is the imaging device according to the sixth embodiment of the present invention, the near infrared light is applied to the near infrared light absorbing film 140 formed on the plate 217 having the near infrared light absorption function. Since it contains an organic pigment that absorbs, it is possible to cut light in the near infrared region without dependence on the angle of incidence to light absorption, without using blue glass, which is generally used as a material for a filter for absorbing light in the near infrared region. It shows an effect.

According to the camera structure applied to the portable communication device A which is the imaging device according to the sixth embodiment of the present invention, at least both sides of the inner transparent plate 240 on the basis of the transparent glass 220 are visible. Since an anti-reflection layer 230 for preventing reflection is provided, more incident light can be received, and reflected light originating from the inner transparent plate 240, particularly reflected light from the imaging element 70 itself, is again an inner transparent plate It is prevented from being reflected on the 240 and returning to the imaging element 70, thereby exhibiting a remarkable effect of improving the image quality.

10 is a view for explaining the effect of the present invention by comparing an image captured with a conventional camera structure and an image captured with a camera structure according to the third embodiment of the present invention.

Fig. 10A shows an explanatory diagram for explaining the experimental method of the experiment performed in the conventional camera structure. In the experiment, the light emission was imaged using a light emitting diode having a specific center wavelength as a light source. In the experiment, a light emitting diode having a center wavelength of 460 nm was used as the light source 300. In order to easily see the generated flare phenomenon or ghost phenomenon, a low reflection material 320 is disposed in the background of the light source 300 and a high reflection material 310 is placed around the low reflection material 320.

When the lens is directed toward a light source having a large light intensity, a phenomenon in which unnecessary images are reflected through repeated reflection of light on the lens surface is called a flare phenomenon or a ghost phenomenon. A phenomenon in which a part of the image is excessively exposed is called a flare phenomenon, and a phenomenon in which unnecessary unnecessary images are reflected through repeated reflection of light from the lens surface is called a ghost phenomenon.

A conventional camera structure includes a cover glass 350, an optical lens group 330, a near-infrared light cut filter 340, and an imaging element 70 in turn from the incident side of light. The near-infrared light cut filter 340 is disposed between the optical lens group 330 and the imaging element 70.

10B is a cross-sectional view of a conventional cover glass 350. The cover glass 350 includes an anti-reflection film 120 on the transparent glass 360. The antireflection film 120 is provided on the optical lens group 330 side of the transparent glass 360.

10C is a cross-sectional view of a conventional near-infrared light cut filter 340. The near-infrared light cut filter 340 is provided with a near-infrared light reflecting film 390 on the incident side of light based on the blue glass 380 as a base material, and has an anti-reflection layer 230 on the imaging element 70 side. Here, the blue glass 380 has a function of absorbing light in the near infrared region.

Fig. 10D is an image captured by the imaging element 70 of the conventional camera structure described in Figs. 10A to 10C. It can be seen that the petal-shaped ghost (G) is generated around the light source (300), and the image quality is deteriorated. Such a ghost phenomenon may occur even when the center wavelength of the light source 300 is changed to 420 nm to 660 nm.

10 (E) is an explanatory diagram for explaining an experiment method of an experiment performed in the camera structure according to the third embodiment of the present invention. In the experiment, a light emitting diode having a center wavelength of 460 nm was used as the light source 300, as in the experiments of FIGS. 10 (A) to 10 (D) described above. The camera structure according to the third embodiment of the present invention includes, in turn, a cover glass 400 having an optical filter function, an optical lens group 330, an inner transparent plate 450, and an imaging element (from an incident side of light) 70). The inner transparent plate 450 is disposed between the optical lens group 330 and the imaging element 70.

10F is a cross-sectional view of the cover glass 400 having an optical filter function in the camera structure according to the embodiment of the present invention. The cover glass 400 having an optical filter function is based on the transparent glass 360, and includes an antireflection film 120 on the incident side of light based on the transparent glass 360, and the optical lens group 330 A near-infrared light cut layer 395 is provided on the side. The near-infrared light cut layer 395 is not described in detail here, but has a near-infrared light absorbing film 140 and a near-infrared light reflecting film 150 (see Fig. 6B).

10G is a cross-sectional view of the inner transparent plate 450 in the camera structure according to the embodiment of the present invention. The inner transparent plate 450 is based on a transparent glass 360, and an anti-reflection layer 230 is provided on both sides of the transparent glass 360.

The specific structure and manufacturing method of the near-infrared reflective film 150, the near-infrared absorbing film 140, and the anti-reflective layer 230 are the same as those in the first embodiment, and thus description thereof is omitted.

Fig. 10H is an image captured by the camera structure according to the embodiment of the present invention. Although strong light is received around the light source 300, ghosts as shown in FIG. 10 (D) do not occur, and it can be seen that the image quality is improved.

The laminated structure of the camera structure, the imaging device, and the cover glass according to the present invention is not limited to the above-described embodiment, and it is needless to say that various changes can be made without departing from the gist of the present invention.

For example, applying a laminated structure and a camera structure of the cover glass according to the present invention to a so-called dual camera in which two camera modules used as a camera of a portable communication device such as a smart phone are combined has great effects. In a dual camera, two camera modules are usually arranged side by side. In a dual camera, images are recorded under two different conditions, and by combining them, exposure or aperture of about a single-lens reflex camera can be adjusted. In the conventional camera structure, two optical filters are required, but when the cover glass provided with the optical filter function according to the present invention is used, since the optical filter in the camera module can be omitted, the assembling process is not only simplified. , Even with one cover glass, it is possible to acquire an image with a higher image quality than when using an optical filter.

Moreover, the cover glass of the camera of a portable communication device, such as a smart phone, is normally provided independently from the smart phone case 20, as shown in FIG. 11 (A). However, in order to improve the design, it is also conceivable to cover the surface of the smart phone case 20 with glass having one continuous optical filter function. In that case, the cover glass 100 with the optical filter function according to the first embodiment of the present invention, the cover glass 210 with the optical filter function, or the cover glass 215 with the near-infrared light reflection function ) Can be used. By setting it as such a structure, the smart phone case 20 which has an integral smooth surface including a camera part can be realized.

As another modified embodiment, it is also conceivable to reverse the stacking order of the near-infrared light absorbing film 140 and the near-infrared light reflecting film 150. That is, from the imaging element 70 side, in order, it is comprised like the near-infrared light absorption film 140, the near-infrared light reflection film 150, and the crystallization glass 130. With such a configuration, since the near-infrared light absorbing film 140 relatively weak to heat can be formed after laminating the near-infrared light reflecting film 150, when forming the near-infrared reflecting film 150, it is inexpensive but easily deposited at high temperatures. A film forming means such as a device can be used. Further, by attaching a film or the like having a near-infrared light absorption function, a near-infrared light reflection function, an anti-reflection function, etc. to the base material glass or synthetic resin film, the cover glass structure according to the present invention and the inner transparent plate can be realized, if possible. You can also use the method.

For example, as a means for realizing the near-infrared light absorption function, for example, as a substrate, a thin plate of synthetic resin containing at least a part of an organic dye that absorbs light in the near-infrared region may be used. In addition, similar to the conventional near-infrared light cut filter, a so-called blue glass plate that absorbs light in the near-infrared region can also be used. It is conceivable to realize this by attaching a film that cuts near-infrared light on a transparent plate.

1 Camera module
10 cover glass
20 smartphone case
30 magnet holder
40 lens carrier
50 lens units
60 optical filters
70 imaging device
80 substrates
100 Cover glass with optical filter function
110 antifouling coating film
120 anti-reflection film
130 crystallized glass
140 Near infrared light absorption film
150 Near Infrared Reflector
160 incident surface
170 exit surface
180 measurement target
190 incident light
200 vertical axis
210 Cover glass with optical filter function
215 Cover glass with near infrared light reflection function
217 Plate with near infrared light absorption function
220 transparent glass
222 transparent synthetic resin film
230 anti-reflection film
232 mose eye structure
240 inner transparent plate
Inner transparent plate based on 242 transparent synthetic resin film
244 Inner transparent plate with near infrared light absorption
300 light source
310 High reflective material
320 Low reflective material
330 optical lens group
340 near infrared cut filter
350 cover glass
360 transparent glass
370 antireflection film
380 blue glass
390 near-infrared ray reflector
395 Near infrared cut layer
400 Cover glass with optical filter function
450 inner transparent plate
A mobile communication device
G Ghost

Claims (24)

A cover glass that is directly fixed to the case of an information communication device and protects the internal camera module from the outside,
The inside of the cover glass is provided with the camera module disposed as a separate body independent of the case,
The camera module includes an optical lens group, an imaging element for receiving light incident through the cover glass and the optical lens group, and an inner transparent plate disposed between the optical lens group and the imaging element and transmitting light. By having, it has a structure in which an optical component is not disposed in a space between the optical lens group and the cover glass,
The cover glass,
A near-infrared light absorbing film that absorbs light in the near-infrared region,
It has a light reflecting film that reflects light in the ultraviolet region and light in the near infrared region,
The cover glass, on the surface of the camera module side, comprises the near-infrared light absorbing film and the light reflecting film in this order from the incident side of light,
The light reflection film is a dielectric multilayer film,
In the camera module,
Without placing an optical component in the space between the optical lens group and the cover glass,
A camera structure characterized by not arranging an optical filter that reflects light in the near infrared region. The method according to claim 1,
The dielectric multilayer film is formed by stacking a plurality of types of oxide films having different refractive indices, and the adjacent oxide films are oxide films of different types. The method according to claim 1 or 2,
The inner transparent plate further comprises a near-infrared light absorbing portion that absorbs light in the near-infrared region. The method according to claim 3,
The near infrared light absorbing portion is a camera structure, characterized in that it comprises an organic pigment. The method according to claim 1 or 2,
The inner transparent plate is a camera structure, characterized in that a synthetic resin film. The method according to claim 1 or 2,
The thickness of the inner transparent plate is a camera structure, characterized in that less than 0.2mm. The method according to claim 1 or 2,
The inner transparent plate is provided with at least an anti-reflection layer for preventing reflection of light in the visible region. The method according to claim 7,
And an anti-reflection layer that prevents reflection of light in at least a visible region on both sides of the inner transparent plate. The method according to claim 7,
The anti-reflection layer is a camera structure characterized in that the micro-protrusion structure made of fine projections formed on the surface of the inner transparent plate. The method according to claim 7,
The anti-reflection layer is a camera structure, characterized in that the coating film formed on the surface of the inner transparent plate. An information communication device comprising the camera structure according to claim 1 or 2. delete delete delete delete delete delete delete delete delete delete delete delete delete

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