JP5854014B2 - Optical apparatus and imaging apparatus - Google Patents

Description

The present invention relates to the technical field of optical devices and imaging devices. More specifically, the present invention relates to a technical field that achieves good color reproducibility and the like in a red region by adjusting spectral characteristics of light incident on an image sensor.

JP 2004-345680 A

  In recent years, there has been an increasing demand for downsizing image pickup devices such as digital video cameras and digital still cameras while ensuring high image quality of images and videos.

  In order to meet this demand, an image pickup apparatus is proposed in which a high-density CCD (Charge Coupled Device) or a high-density CMOS (Complementary Metal-Oxide Semiconductor) is mounted as an image pickup element of the image pickup apparatus and the image pickup optical system is miniaturized. ing.

  In general, in an imaging optical system using an imaging element, many techniques for realizing high resolution are known as means for improving image quality. On the other hand, it is important to ensure good color reproducibility of images and videos in order to achieve high image quality in addition to high resolution, and an optical element arranged on the optical path to ensure good color reproducibility Spectral characteristics greatly affect.

  For example, as a conventional imaging device, there is an imaging device in which an optical element having an infrared absorption function is arranged on an optical path of an imaging optical system (see, for example, Patent Document 1). In an imaging apparatus having such an optical element, it is necessary to ensure good spectral characteristics of the optical element as described above.

  In addition, with the miniaturization of the imaging optical system and the lens barrel including the imaging optical system, there is a reflection ghost caused by reflection of light in an optical element constituting the lens barrel, in particular, an optical element that interferes with ultraviolet rays or infrared rays by a multilayer film. The situation is likely to occur. Therefore, it is important to suppress the generation of reflection ghosts in order to achieve both high image quality and downsizing.

  10 to 12 are graphs showing the spectral characteristics of the conventional optical element. In each figure, the upper graph shows the relationship between the wavelength and the spectral transmittance, and the lower graph shows the relationship between the wavelength and the spectral reflectance on each surface. In the lower graph, “A surface” is a surface facing the object side in the optical element, and “B surface” is a surface facing the image side in the optical element.

  FIG. 10 shows an optical element in which white plate glass is used as a substrate, a multilayer film for spectral adjustment is formed on the surface facing the object side of the substrate, and an antireflection film is formed on the surface facing the image side of the substrate. The measured value is shown.

  In FIGS. 11 and 12, infrared absorbing glass is used as a base material, a multilayer film for spectral adjustment is formed on the surface facing the object side of the base material, and an antireflection film is formed on the surface facing the image side of the base material. The measured values for the two types of optical elements are shown.

  As shown in FIG. 10, in the optical element in which white plate glass is used as the base material, since the base material does not have an infrared absorbing action, the spectral transmittance changes rapidly in the vicinity of 650 nm. Therefore, unnecessary light is incident on the image sensor as compared with the optical elements shown in FIGS.

  Further, it is known that the wavelength region of light that easily contributes to the generation of red reflection ghost is about 600 nm to about 680 nm. However, in any of the optical elements shown in FIGS. The spectral reflectance is increased in the wavelength region, and a red reflection ghost is likely to occur.

  In a conventional imaging device in which an optical element having an infrared absorbing function is arranged, high resolution is achieved to achieve high image quality, but as described above, due to the occurrence of a red reflection ghost, There is a problem that securing of color reproducibility is insufficient.

  Further, although the optical element disposed on the optical path of the imaging optical system has a constant thickness, there is a problem that the imaging apparatus cannot be sufficiently downsized due to the thickness of the optical element.

Accordingly, it is an object of the present invention to overcome the above-described problems and to achieve good color reproducibility in the red region and downsizing.

In order to solve the above-described problems, the optical device includes a plurality of lenses or lens groups arranged on the optical path and an optical element, and the optical element is formed of a film-like resin material having an infrared absorption function. And a multilayer film that is formed on each of the surface facing the object side and the surface facing the image side of the substrate and reflects light in the near infrared region, and the spectral transmittance of the optical element and the Spectral reflectances on both the surface facing the object side and the surface facing the image side satisfy the following conditional expressions (1) to (4), and the surface facing the object side and the surface facing the image side The spectral reflectance satisfies the following conditional expression (5).
(1) 0.75 <T _{IRCF (600)} / T _{IRCF (540)} <0.95
(2) 615 <λ _LT50% <670
(3) | T _{IRCF (700)} / T _{IRCF (540)} | <0.05
(4) 680 ≦ λ _LR50%
(5) λ _LR50% [A] ≧ λ _LR50% [B]
However,
T _{IRCF (600)} : spectral transmittance of light having a wavelength of 600 nm T _{IRCF (540)} : spectral transmittance of light having a wavelength of 540 nm λ _LT 50%: wavelength T _{IRCF (700} of near infrared light at which the spectral transmittance becomes 50% ₎ : Spectral transmittance λ _LR50% of light having a wavelength of 700 nm: Wavelength λ _{LR50% of} near-infrared light at which the spectral reflectance is 50 _% [A]: Near spectral reflectance at a surface facing the object side is 50% Infrared light wavelength λ _{LR 50%} [B]: The wavelength of near-infrared light at which the spectral reflectance at the image-facing surface is 50%, and the unit of wavelength is nm.

Therefore, in the optical device, infrared rays are absorbed by the base material, and spectral characteristics are adjusted by the multilayer film, so that the spectral reflectance in the red region is lowered. Further, by satisfying conditional expression (5), the spectral reflectance and reflection wavelength region from the red wavelength region to the near infrared region are larger on the surface facing the image side than on the surface facing the object side. Become.

Furthermore, in order to solve the above-described problems, the optical device includes a plurality of lenses or lens groups arranged on the optical path and an optical element, and the optical element is made of a film-like resin material having an infrared absorption function. Spectral transmittance of the optical element, comprising: a formed base material; and a multilayer film that is formed on each of the surface facing the object side and the surface facing the image side of the base material and reflects the light in the near infrared region. And the spectral reflectances on both the object-facing surface and the image-facing surface satisfy the following conditional expressions (1) to (4), and the near-infrared region of the surface facing the image side The optical element is arranged such that the spectral reflectance is higher than the spectral reflectance in the near infrared region on the surface facing the object side .
(1) 0.75 <T _{IRCF (600)} / T _{IRCF (540)} <0.95
(2) 615 <λ _LT50% <670
(3) | T _{IRCF (700)} / T _{IRCF (540)} | <0.05
(4) 680 ≦ λ _LR50%
However,
T _{IRCF (600)} : spectral transmittance of light having a wavelength of 600 nm T _{IRCF (540)} : spectral transmittance of light having a wavelength of 540 nm λ _LT 50%: wavelength T _{IRCF (700} of near infrared light at which the spectral transmittance becomes 50% ₎ : Spectral transmittance λ _LR50% of light having a wavelength of 700 nm: wavelength of near infrared light at which the spectral reflectance is 50%, and the unit of wavelength is nm.

Therefore, in the optical device, infrared rays are absorbed by the base material, and spectral characteristics are adjusted by the multilayer film, so that the spectral reflectance in the red region is lowered.

Furthermore, in order to solve the above-described problems, the imaging apparatus includes a plurality of lenses or lens groups arranged on the optical path, an optical element, and an imaging element, and the optical element is a film-like film having an infrared absorption function. A substrate formed of a resin material, and a multilayer film formed on each of a surface facing the object side and a surface facing the image side of the substrate and reflecting light in a near infrared region , The spectral transmittance and the spectral reflectance on both the object-facing surface and the image-facing surface satisfy the following conditional expressions (1) to (4), and the object-facing surface and the image The spectral reflectance on the side facing the surface satisfies the following conditional expression (5), and the optical element is arranged between the lens arranged on the most image side of the plurality of lenses and the imaging element. Is.
(1) 0.75 <T _{IRCF (600)} / T _{IRCF (540)} <0.95
(2) 615 <λ _LT50% <655
(3) | T _{IRCF (700)} / T _{IRCF (540)} | <0.05
(4) 680 ≦ λ _LR50%
(5) λ _LR50% [A] ≧ λ _LR50% [B]
However,
T _{IRCF (600)} : spectral transmittance of light having a wavelength of 600 nm T _{IRCF (540)} : spectral transmittance of light having a wavelength of 540 nm λ _LT 50%: wavelength T _{IRCF (700} of near infrared light at which the spectral transmittance becomes 50% ₎ : Spectral transmittance λ _LR50% of light having a wavelength of 700 nm: wavelength of near-infrared light having a spectral reflectance of 50%
λ _{LR 50%} [A]: wavelength of near-infrared light at which the spectral reflectance at the surface facing the object side is 50%
[ lambda ] _{LR 50%} [B]: The wavelength of near-infrared light at which the spectral reflectance on the surface facing the image side is 50%, and the unit of wavelength is nm.

Therefore, in the imaging device, infrared rays are absorbed by the base material, and spectral characteristics are adjusted by the multilayer film, so that the spectral reflectance in the red region is lowered.

According to the present invention, infrared rays are absorbed by the base material, and spectral characteristics are adjusted by the multilayer film, so that the spectral reflectance in the red region is lowered. Further, by satisfying conditional expression (5), the spectral reflectance and reflection wavelength region from the red wavelength region to the near infrared region are larger on the surface facing the image side than on the surface facing the object side. Become.

2 to 9 show an embodiment of the present invention, and this figure is a conceptual diagram showing a configuration of an imaging apparatus. It is a conceptual diagram which shows the structure of an optical element. It is a conceptual diagram which shows the structure of another imaging device. It is a conceptual diagram which shows the structure of another imaging device. It is a graph which shows the spectral transmission characteristic and spectral reflection characteristic of the optical element in a 1st Example. It is a graph which shows the spectral transmission characteristic and spectral reflection characteristic of the optical element in a 2nd Example. It is a graph which shows the spectral transmission characteristic and spectral reflection characteristic of the optical element in a 3rd Example. It is a graph which compares and shows a spectral reflection characteristic about the conventional optical element and the optical element in a 1st Example. It is a block diagram which shows one Embodiment of this invention imaging device. It is a graph which shows the spectral transmission characteristic and spectral reflection characteristic of the conventional optical element. It is a graph which shows the spectral transmission characteristic and spectral reflection characteristic of another conventional optical element. It is a graph which shows the spectral transmission characteristic and spectral reflection characteristic of another conventional optical element.

Embodiments of an optical apparatus and an imaging apparatus according to the present invention will be described below with reference to the accompanying drawings.

In the embodiment described below, the optical apparatus and the imaging apparatus of the present invention are applied to a digital still camera.

  The scope of application of the present invention is not limited to a digital still camera, an imaging optical system provided in the digital still camera, and an optical element provided in the imaging optical system. The present invention includes, for example, a digital video camera, a camera incorporated in a mobile phone, a personal computer, a PDA (Personal Digital Assistant), an imaging optical system provided in these various cameras, and these various imaging optical systems. The present invention can be widely applied to provided optical elements.

[overall structure]
As shown in FIG. 1, the imaging apparatus (digital still camera) 1 has, for example, five lens groups 2, 2,... And an imaging element 3 such as a CCD or CMOS arranged on the optical path. In FIG. 1, the type of the five-group configuration is shown as an example of the imaging device 1, but the number of lens groups 2 of the imaging device 1 is arbitrary. The lens group (first lens group) 2 positioned closest to the object side is provided with a prism 2a that bends the optical path by 90 °.

  The image sensor 3 is disposed on the most image side on the optical path.

  An optical element 4 is arranged between the imaging element 3 and the lens 2b located on the most image side in the lens group (fifth lens group) 2 arranged on the most image side.

  A cover glass 5 is disposed between the optical element 4 and the image sensor 3. An aperture stop 6 is arranged on the image side of the third lens group (third lens group) 2 arranged third from the object side to the image side.

  In the imaging apparatus 1, an imaging optical system is configured by the lens groups 2, 2,..., The imaging element 3, the optical element 4, the cover glass 5, the aperture stop 6, and the like as described above.

  In the imaging device 1 having such a prism 2a, the optical path is bent at a right angle by the prism 2a, so that the thickness can be reduced.

[Configuration of optical element]
As shown in FIG. 2, the optical element 4 has an infrared ray absorbing function, and is formed on both the base material 8 formed of a film-like resin material, the surface facing the object side, and the surface facing the image side of the base material 8. Each of the multilayer films 9 and 10 is formed.

  In the optical element 4, since the base material 8 is formed of a film-like material, it can be sufficiently thinned. Therefore, it is possible to reduce the size of the imaging optical system and the imaging apparatus 1. In particular, in a so-called collapsible type imaging apparatus in which a lens barrel is housed during non-shooting and the lens barrel protrudes during shooting. It is possible to reduce the thickness.

  In addition, it is preferable to make the total thickness of the base material 8 and the multilayer films 9 and 10 of the optical element 4 120 μm or less because the above-described advantage of thinning becomes particularly remarkable.

  The base material 8 has an infrared ray absorbing action. Specifically, it has an absorption characteristic from the red wavelength region to the near infrared region (about 540 nm to about 700 nm).

  Accordingly, it is possible to optimally adjust the spectral intensity balance of light incident on the image sensor 3 (for example, the balance of light intensity in the blue region, green region, and red region), and to adjust the white balance of images and videos. Color reproduction can be performed satisfactorily.

  In addition, generation of color noise due to excessive electrical color adjustment can be prevented.

  Furthermore, since it is possible to suppress the occurrence of red reflection ghosts that may be caused by unnecessary reflection of light in the image pickup optical system and cause deterioration in image quality, it is possible to achieve high image quality.

  Furthermore, since the optical element 4 is formed with the multilayer films 9 and 10 for adjusting the spectral characteristics on both surfaces of the base material 8, the spectral characteristics that the base material 8 has insufficient absorption characteristics alone are insufficient. Can be fine-tuned. Therefore, it is possible to secure transmission spectral characteristics that allow optimal color adjustment in images and videos.

  In addition, since the multilayer films 9 and 10 are formed on both surfaces of the substrate 8, even when the substrate 8 is formed of a film-like resin material having low rigidity, the stress due to the multilayer films 9 and 10 is applied to the substrate. 8 can be balanced on both sides. Therefore, it is possible to improve the planar accuracy of the optical element 4 by suppressing the occurrence of warping and bending to the utmost, preventing the optical performance of the imaging optical system from being deteriorated, and suppressing the occurrence of reflection ghosts. be able to.

  In order to maximize the effect of improving the planar accuracy of the optical element 4 described above, the number of layers of the multilayer films 9 and 10 is made substantially the same, and the stress balance on both sides of the substrate 8 is maintained. It is desirable.

The optical element 4 is configured such that the spectral transmittance and the spectral reflectance on both the object-facing surface and the image-facing surface satisfy the following conditional expressions (1) to (4).
(1) 0.75 <T _{IRCF (600)} / T _{IRCF (540)} <0.95
(2) 615 <λ _LT50% <670
(3) | T _{IRCF (700)} / T _{IRCF (540)} | <0.05
(4) 680 ≦ λ _LR50%
However,
T _{IRCF (600)} : spectral transmittance of light having a wavelength of 600 nm T _{IRCF (540)} : spectral transmittance of light having a wavelength of 540 nm λ _LT 50%: wavelength T _{IRCF (700} of near infrared light at which the spectral transmittance becomes 50% ₎ : Spectral transmittance λ _LR50% of light having a wavelength of 700 nm: wavelength of near infrared light at which the spectral reflectance is 50%, and the unit of wavelength is nm.

  Conditional expressions (1) to (3) are expressions that define the spectral transmission characteristics of the optical element 4 from the red wavelength region to the near infrared region.

  If the upper limit or lower limit of conditional expression (1) is exceeded, the amount of light in the vicinity of the wavelength of 600 nm becomes excessively unbalanced with respect to the amount of light in the visible light region other than that region, making it difficult to adjust white balance in color reproduction. Become. In addition, excessive electrical signal gain associated with image processing easily causes color noise, resulting in degradation of image quality.

  If the upper limit of conditional expression (2) is exceeded, the cut-off wavelength for infrared transmission in the optical element 4 becomes too long, and the amount of transmitted light and the transmission wavelength range in the near-infrared region become too large. It will not be possible to perform sufficient color adjustment. For example, it is difficult to adjust the white balance, or the imaging device 3 is exposed to light in an infrared region that cannot be visually recognized.

  On the contrary, if the lower limit of conditional expression (2) is exceeded, the cutoff wavelength of infrared transmission in the optical element 4 becomes too short, and the amount of transmitted light and the transmission wavelength range in the red region become too small. It becomes impossible to perform sufficient color adjustment of the image. In particular, the red and purple color reproducibility tends to be adversely affected.

  When the upper limit of conditional expression (3) is exceeded, the amount of light in the vicinity of the wavelength of 700 nm becomes too large, and the amount of light in the near infrared region incident on the image sensor 3 becomes too large. In particular, it adversely affects the color reproducibility of red and black. For example, it is difficult to adjust the white balance, or the imaging device 3 is exposed to light in an infrared region that cannot be visually recognized.

  Conditional expression (4) is an expression that defines the spectral reflection characteristics of the optical element 4 from the red wavelength region to the near infrared region.

  When the lower limit of the conditional expression (4) is exceeded, the spectral reflectance and the reflection wavelength region from the red region to the infrared region in the optical element 4 become too large, and a red reflection ghost caused by light reflection in the optical element 4 occurs. It becomes prominently generated, and the image quality is greatly deteriorated. The red reflection ghost is generated, for example, by reflection between the optical element 4 and the imaging element 3 or the lens of the imaging optical system.

  In addition, the red reflection ghost has an influence that the multilayer films 9 and 10 interfere with the light incident on the optical element 4 as the incident angle of the light that causes the ghost with respect to the optical element 4 increases. Becomes higher. Therefore, when the image pickup optical system and the image pickup apparatus 1 are reduced in size, the incident angle of light that causes ghosts with respect to the optical element 4 increases, or the density of light incident on the optical element 4 increases. In particular, a red reflection ghost is likely to occur.

  As described above, when the optical element 4 satisfies the conditional expressions (1) to (4), the occurrence of red reflection ghost is suppressed, a good white balance is ensured, and the good color reproduction in the red region is achieved. Therefore, the image quality can be greatly improved. In particular, as described above, even when the incident angle with respect to the optical element 4 of light that causes ghosts due to downsizing of the imaging device 1 is increased or the density of incident light is increased, Satisfying conditional expressions (1) to (4) can ensure good color reproducibility in the red region.

  In the image sensor 1, the optical element 4 is disposed between the lens 2 b disposed on the most image side of the image capturing optical system and the image sensor 3.

  By disposing the optical element 4 between the lens 2b and the imaging element 3 in this way, the spherical aberration is disturbed as compared with the case where the optical element 4 is disposed near the aperture stop 6 where the distance between the principal ray and the peripheral ray is increased. And deterioration can be reduced. Therefore, it is possible to suppress degradation of the resolution of the imaging optical system, and it is possible to reduce the amount of back focus shift, which is a concern in manufacturing and temperature change.

  In general, an imaging apparatus having an imaging element is designed to approach an image-side telecentric system in order to make the image plane illuminance uniform in the imaging optical system. When designed to approach the image-side telecentric system in this way, in order to reduce the size of the image-capturing optical system, due to the optical design, between the lens disposed on the most image side of the image-capturing optical system and the image-capturing element. It is relatively easy to form an arrangement space.

  Therefore, as in the imaging apparatus 1, the optical element 4 is disposed in the arrangement space that can be formed relatively easily by arranging the optical element 4 between the lens 2b arranged on the most image side on the optical path and the imaging element 3. The image pickup apparatus 1 can be easily downsized.

In the imaging device 1, it is desirable that the spectral reflectances on the surface facing the object side and the surface facing the image side of the optical element 4 satisfy the following conditional expression (5).
(5) λ _LR50% [A] ≧ λ _LR50% [B]
However,
λ _LR50% [A]: wavelength of near-infrared light at which the spectral reflectance at the surface facing the object side is 50% λ _LR50% [B]: near red at which the spectral reflectance at the surface facing the image side is 50% The wavelength of outside light.

  Conditional expression (5) is an expression that defines the orientation of the optical element 4. That is, it is defined that the optical element 4 is arranged so that the surface having a high spectral reflectance from the red wavelength region to the near infrared region faces the image sensor 3 side.

  When the optical element 4 is arranged in the state where the directions of the surfaces are opposite to the conditional expression (5), the spectral reflectance and the reflected wavelength region from the red wavelength region to the near infrared region are directed toward the object side. The surface is larger than the surface facing the image side. Therefore, the frequency of occurrence of a red reflection ghost due to reflection between the optical elements 4 such as the lenses 2, 2,... Arranged on the object side with respect to the optical element 4 is increased, and the image quality is deteriorated.

  Even when the optical element 4 is arranged in a direction that satisfies the conditional expression (5), a reflection ghost may occur between the imaging element 3 and the surface facing the image side of the optical element 4. . However, as compared with the case where the optical element 4 is arranged in the direction contrary to the conditional expression (5), the number of reflection ghost patterns associated with the number of members that reflect light, the angle condition of incident light, and reflection in an image or video. Considering the size and shape of the ghost image, the image quality can be improved when the optical element 4 is arranged in a direction that satisfies the conditional expression (5).

  In addition, when the optical element 4 is arranged in a direction that satisfies the conditional expression (5), the deterioration of the image quality due to the generation of the reflection ghost causes the optical element 4 to satisfy the conditional expressions (1) to (4). Can be prevented.

  In the optical element 4, the base material 8 is formed of a film-like resin material. As the material of the base material 8, for example, it is desirable to use a polyolefin resin.

  Polyolefin resins have the characteristics of excellent optical performance (high transparency, low birefringence, high Abbe number, etc.), heat resistance, and low water absorption. Therefore, by forming the base material 8 with a polyolefin-based resin, it is possible to ensure good characteristics of the optical element 4 even when the imaging device 1 is used under severe temperature conditions and severe humidity conditions. it can.

  Moreover, polyolefin resin is cheaper than the infrared rays absorption glass conventionally used as a material of a base material. Therefore, the manufacturing cost of the imaging device 1 and the imaging optical system can be reduced by forming the base material 8 from a polyolefin resin.

  Furthermore, since the polyolefin-based resin has excellent characteristics in moldability, for example, the optical element 4 can be made thinner and thinner than when using an infrared absorbing glass as a base material. For example, the imaging device 1 and the imaging optical system can be reduced in size to 120 μm or less.

  As described above, when a polyolefin-based resin is used as the base material 8 of the optical element 4, a coloring material that is an organic dye having light absorption characteristics in the near infrared region as an infrared absorbing material, such as an anthocyanin dye, It is desirable to mix a cyanine dye.

  For example, anthocyanin dyes have been reported to be improved with respect to heat resistance and light resistance (for example, Japanese Patent Application Laid-Open No. 2003-292810), and stable reliability can be expected even under severe temperature conditions. Therefore, environmental considerations that are difficult to achieve with synthetic colorants can be easily achieved.

  Further, when an organic dye is used as the infrared absorbing material, it is possible to ensure good mixing of the colorant with the polyolefin resin.

  In the above description, the imaging device 1 having the five lens groups 2, 2,... Is shown as an example, but the optical element 4 is provided in the imaging device 1A or the imaging device 1B as shown below, for example. (See FIGS. 3 and 4).

  As shown in FIG. 3, the imaging apparatus 1A has, for example, three lens groups 2A, 2A, 2A and an imaging element 3 such as a CCD or a CMOS arranged on the optical path.

  An optical element 4 is arranged between the imaging element 3 and the lens 2c located closest to the image side in the lens group (third lens group) 2A arranged closest to the image side.

  A cover glass 5 is disposed between the optical element 4 and the image sensor 3. An aperture stop 6 is disposed on the image side of the second lens group (second lens group) 2A arranged from the object side to the image side.

  In the imaging apparatus 1A, the imaging optical system is configured by the lens groups 2A, 2A, 2A, the imaging element 3, the optical element 4, the cover glass 5, the aperture stop 6, and the like as described above.

  As shown in FIG. 4, the imaging device 1B includes, for example, four lens groups 2B, 2B,... And an imaging element 3 such as a CCD or CMOS on the optical path.

  An optical element 4 is arranged between the imaging element 3 and the lens 2d located on the most image side in the lens group (fourth lens group) 2B arranged on the most image side.

  A low-pass filter 7 and a cover glass 5 are disposed in order from the object side between the optical element 4 and the imaging element 3. An aperture stop 6 is arranged on the object side of the lens group (third lens group) 2B arranged third from the object side to the image side.

  In the imaging apparatus 1B, an imaging optical system is configured by the lens groups 2B, 2B,..., The imaging element 3, the optical element 4, the cover glass 5, the aperture stop 6, the low-pass filter 7, and the like as described above. Yes.

  In the imaging apparatus 1 </ b> B having such a low-pass filter 7, the generation of moire fringes can be prevented by the low-pass filter 7.

[Example]
Specific examples of the optical element 4 will be described below (see FIGS. 5 to 7). The optical elements 4 in the following first, second, and third examples each have a thickness of 100 μm. In the graphs shown in FIGS. 5 to 7, the upper graph shows the relationship between the wavelength and the spectral transmittance, and the lower graph shows the relationship between the wavelength and the spectral reflectance on each surface. In the lower graph, “A surface” is a surface facing the object side in the optical element 4, and “B surface” is a surface facing the image side in the optical element 4.

  FIG. 5 is a graph showing the first embodiment.

In the first embodiment,
(1) T _{IRCF (600)} / T _{IRCF (540)} = 0.906
(2) λ _LT50% = 650 nm
(3) | T _{IRCF (700)} / T _{IRCF (540)} | = 0.002
(4) λ _LR50% = 729 nm, 697 nm
(5) λ _LR50% [A] = 729 nm, _λLR50% [B] = 697 nm
Conditional expression (1), conditional expression (2), conditional expression (3), conditional expression (4), and conditional expression (5) are satisfied.

  As shown in FIG. 5, in the first embodiment, in the red region (wavelength of about 600 nm to about 700 nm), the spectral transmittance gradually decreases as it approaches the long wavelength side.

  In addition, the spectral reflectance is low in the wavelength range of about 600 nm to about 680 nm, which is likely to contribute to the generation of red reflection ghosts on both the A and B planes, and higher on the longer wavelength side.

  Therefore, in the first embodiment, a good white balance can be secured and a good color reproducibility in the red region can be realized.

  FIG. 6 is a graph showing the second embodiment.

In the second embodiment,
(1) T _{IRCF (600)} / T _{IRCF (540)} = 0.946
(2) λ _LT50% = 655 nm
(3) | T _{IRCF (700)} / T _{IRCF (540)} | = 0.002
(4) λ _LR50% = 729 nm, 697 nm
(5) λ _LR50% [A] = 729 nm, _λLR50% [B] = 697 nm
Conditional expression (1), conditional expression (2), conditional expression (3), conditional expression (4), and conditional expression (5) are satisfied.

  As shown in FIG. 6, in the second embodiment, in the red region (wavelength of about 600 nm to about 700 nm), the spectral transmittance gradually decreases as it approaches the long wavelength side.

  In addition, the spectral reflectance is low in the wavelength range of about 600 nm to about 680 nm, which is likely to contribute to the generation of red reflection ghosts on both the A and B planes, and higher on the longer wavelength side.

  Therefore, in the second embodiment, a good white balance can be secured and a good color reproducibility in the red region can be realized.

  FIG. 7 is a graph showing the third embodiment.

In the third embodiment,
(1) T _{IRCF (600)} / T _{IRCF (540)} = 0.807
(2) λ _LT50% = 622 nm
(3) | T _{IRCF (700)} / T _{IRCF (540)} | = 0.0001
(4) λ _LR50% = 739 nm, 694 nm
(5) λ _{LR 50%} [A] = 739 nm, λ _{LR 50%} [B] = 694 nm
Conditional expression (1), conditional expression (2), conditional expression (3), conditional expression (4), and conditional expression (5) are satisfied.

  As shown in FIG. 7, in the third embodiment, in the red region (wavelength of about 600 nm to about 700 nm), the spectral transmittance gradually decreases as it approaches the long wavelength side.

  In addition, the spectral reflectance is low in the wavelength range of about 600 nm to about 680 nm, which is likely to contribute to the generation of red reflection ghosts on both the A and B planes, and higher on the longer wavelength side.

  Therefore, in the third embodiment, a good white balance can be secured and a good color reproducibility in the red region can be realized.

  As an example, FIG. 8 shows a comparison of spectral reflectances of the conventional optical element (example shown in FIG. 10) and the optical element 4 in the first embodiment.

  As shown in FIG. 8, in the conventional optical element, the spectral reflectance is increased in the wavelength range of about 600 nm to about 680 nm (range P) that is likely to contribute to the generation of the red reflection ghost. In the optical element 4, the spectral reflectance is increased on the longer wavelength side than about 600 nm to about 680 nm.

  By using the optical element 4 in this manner, since the spectral reflectance becomes higher on the longer wavelength side than the wavelength region of light that easily contributes to the generation of the red reflection ghost, the generation of the red reflection ghost is suppressed, which is favorable. White balance can be ensured and good color reproducibility in the red region can be realized.

[Configuration example of multilayer film]
Table 1 shows an example of the structure of the multilayer film. In the “surface” in the table, “A” indicates a surface facing the object side in the optical element 4, and “B” indicates a surface facing the image side in the optical element 4. The multilayer film 9 of the optical element 4 shown in Table 1 has 19 layers, and the multilayer film 10 has 17 layers.

[One Embodiment of Imaging Device]
FIG. 9 is a block diagram of a digital still camera according to an embodiment of the imaging apparatus of the present invention.

  An imaging device (digital still camera) 100 includes a camera block 10, a camera signal processing unit 20, an image processing unit 30, an LCD (Liquid Crystal Display) 40, an R / W (reader / writer) 50, and a CPU (Central Processing Unit) 60. The input unit 70 and the lens drive control unit 80 are provided.

  The camera block 10 has an imaging function, the camera signal processing unit 20 performs signal processing such as analog-digital conversion of the captured image signal, the image processing unit 30 performs recording / playback processing of the image signal, and the LCD 40 is captured. Displayed images. The R / W 50 writes and reads image signals to and from the memory card 1000, the CPU 60 controls the entire image pickup apparatus 100, the input unit 70 includes various switches that are operated by a user, and the like. The drive control unit 80 controls the driving of the lenses arranged in the camera block 10.

  The camera block 10 includes an image pickup optical system including a zoom lens 11, an image pickup device 12 such as a CCD or CMOS, and the like.

  The camera signal processing unit 20 performs various signal processing such as conversion of the output signal from the image sensor 12 into a digital signal, noise removal, image quality correction, and conversion into a luminance / color difference signal.

  The image processing unit 30 performs compression encoding / decompression decoding processing of an image signal based on a predetermined image data format, conversion processing of data specifications such as resolution, and the like.

  The LCD 40 has a function of displaying various data such as an operation state of the user's input unit 70 and a photographed image.

  The R / W 50 writes the image data encoded by the image processing unit 30 to the memory card 1000 and reads the image data recorded on the memory card 1000.

  The CPU 60 functions as a control processing unit that controls each circuit block provided in the imaging apparatus 100, and controls each circuit block based on an instruction input signal or the like from the input unit 70.

  The input unit 70 includes, for example, a shutter release button for performing a shutter operation, a selection switch for selecting an operation mode, and the like, and outputs an instruction input signal corresponding to an operation by a user to the CPU 60.

  The lens drive control unit 80 controls a motor (not shown) that drives each lens of the zoom lens 11 based on a control signal from the CPU 60.

  The memory card 1000 is a semiconductor memory that can be attached to and detached from a slot connected to the R / W 50, for example.

  Hereinafter, an operation in the imaging apparatus 100 will be described.

  In a shooting standby state, under the control of the CPU 60, an image signal shot by the camera block 10 is output to the LCD 40 via the camera signal processing unit 20 and displayed as a camera through image. In addition, when an instruction input signal for zooming is input from the input unit 70, the CPU 60 outputs a control signal to the lens drive control unit 80, and a predetermined value of the zoom lens 11 is controlled based on the control of the lens drive control unit 80. The lens is moved.

  When a shutter (not shown) of the camera block 10 is operated by an instruction input signal from the input unit 70, the captured image signal is output from the camera signal processing unit 20 to the image processing unit 30 and subjected to compression encoding processing. Converted to data format digital data. The converted data is output to the R / W 50 and written to the memory card 1000.

  The focusing is performed by the lens drive control unit 80 based on a control signal from the CPU 60, for example, when the shutter release button of the input unit 50 is half pressed or when the shutter release button is fully pressed for recording (photographing). This is performed by moving a predetermined lens of the zoom lens 11.

  When reproducing the image data recorded on the memory card 1000, predetermined image data is read from the memory card 1000 by the R / W 50 in accordance with an operation on the input unit 70, and decompressed and decoded by the image processing unit 30. After the processing is performed, the reproduction image signal is output to the LCD 40 and the reproduction image is displayed.

  The specific shapes and structures of the respective parts shown in the above-described best mode are merely examples of the implementation of the present invention, and the technical scope of the present invention is limited by these. It should not be interpreted in a general way.

DESCRIPTION OF SYMBOLS 1 ... Imaging device, 2 ... Lens group, 2b ... Lens, 3 ... Imaging element, 4 ... Optical element, 1A ... Imaging device, 2A ... Lens group, 2c ... Lens, 1B ... Imaging device, 2B ... Lens group, 2d ... Lens, 100 ... imaging device, 12 ... imaging device

Claims (31)

A plurality of lenses or lens groups disposed on the optical path and an optical element;
The optical element includes a film-like resin material substrate formed by having an infrared-absorbing effect, the light in the near-infrared region are formed on both sides of the surface facing the surface and the image side facing the object side of the substrate And a multilayer film that reflects
The spectral transmittance of the optical element and the spectral reflectance on both the surface facing the object side and the surface facing the image side satisfy the following conditional expressions (1) to (4):
An optical apparatus in which spectral reflectances on a surface facing the object side and a surface facing the image side satisfy the following conditional expression (5).
(1) 0.75 <T _{IRCF (600)} / T _{IRCF (540)} <0.95
(2) 615 <λ _LT50% <670
(3) | T _{IRCF (700)} / T _{IRCF (540)} | <0.05
(4) 680 ≦ λ _LR50%
(5) λ _LR50% [A] ≧ λ _LR50% [B]
However,
T _{IRCF (600)} : spectral transmittance of light having a wavelength of 600 nm T _{IRCF (540)} : spectral transmittance of light having a wavelength of 540 nm λ _LT 50%: wavelength T _{IRCF (700} of near infrared light at which the spectral transmittance becomes 50% ₎ : Spectral transmittance λ _LR50% of light having a wavelength of 700 nm: Wavelength λ _{LR50% of} near-infrared light at which the spectral reflectance is 50 _% [A]: Near spectral reflectance at a surface facing the object side is 50% Infrared light wavelength λ _{LR 50%} [B]: The wavelength of near-infrared light at which the spectral reflectance at the image-facing surface is 50%, and the unit of wavelength is nm. A plurality of lenses or lens groups disposed on the optical path and an optical element;
The optical element includes a film-like resin material substrate formed by having an infrared-absorbing effect, the light in the near-infrared region are formed on both sides of the surface facing the surface and the image side facing the object side of the substrate And a multilayer film that reflects
The spectral transmittance of the optical element and the spectral reflectance on both the surface facing the object side and the surface facing the image side satisfy the following conditional expressions (1) to (4):
The optical device is arranged such that a spectral reflectance of a near infrared region on a surface facing the image side is higher than a spectral reflectance of a near infrared region on a surface facing the object side .
(1) 0.75 <T _{IRCF (600)} / T _{IRCF (540)} <0.95
(2) 615 <λ _LT50% <670
(3) | T _{IRCF (700)} / T _{IRCF (540)} | <0.05
(4) 680 ≦ λ _LR50%
However,
T _{IRCF (600)} : spectral transmittance of light having a wavelength of 600 nm T _{IRCF (540)} : spectral transmittance of light having a wavelength of 540 nm λ _LT 50%: wavelength T _{IRCF (700} of near infrared light at which the spectral transmittance becomes 50% ₎ : Spectral transmittance λ _LR50% of light having a wavelength of 700 nm: wavelength of near infrared light at which the spectral reflectance is 50%, and the unit of wavelength is nm. The optical device according to claim 1, wherein the plurality of lenses or lens groups is five. The optical device according to claim 1, wherein the plurality of lenses or lens groups is six. The optical device according to claim 1, wherein the plurality of lenses or lens groups is seven. The optical device according to claim 1, wherein the plurality of lenses or the lens group includes a lens having a surface having an inflection point on the image side or the object side. The optical device according to claim 6, wherein a lens having a surface having the inflection point is disposed closest to the image side among the plurality of lenses or the lens group. The optical apparatus according to claim 7, wherein the inflection point is provided on an image side surface. The optical device according to claim 7, wherein the inflection point is provided on a surface on the object side. The optical device according to claim 1, wherein the plurality of lenses or the lens group includes a lens having a convex shape and a concave shape on one surface. The optical device according to claim 10, wherein the lens provided with the convex shape and the concave shape is disposed closest to the image side among the plurality of lenses or the lens group. The optical device according to claim 11, wherein the convex shape and the concave shape are provided on an image side surface. The optical device according to claim 11, wherein the convex shape and the concave shape are provided on a surface on the object side. A cover glass is provided on the object side of the image sensor,
The optical device according to claim 1, wherein the optical element is disposed closer to the object side than the cover glass. The optical device according to claim 1, wherein the optical element has a larger image height than the imaging element. A plurality of lenses or lens groups disposed on the optical path, an optical element, and an imaging element;
The optical element includes a film-like resin material substrate formed by having an infrared-absorbing effect, the light in the near-infrared region are formed on both sides of the surface facing the surface and the image side facing the object side of the substrate And a multilayer film that reflects
The spectral transmittance of the optical element and the spectral reflectance on both the surface facing the object side and the surface facing the image side satisfy the following conditional expressions (1) to (4):
Spectral reflectances on the surface facing the object side and the surface facing the image side satisfy the following conditional expression (5):
The optical element is an image pickup apparatus arranged between a lens arranged on the most image side of the plurality of lenses and the image pickup element.
(1) 0.75 <T _{IRCF (600)} / T _{IRCF (540)} <0.95
(2) 615 <λ _LT50% <655
(3) | T _{IRCF (700)} / T _{IRCF (540)} | <0.05
(4) 680 ≦ λ _LR50%
(5) λ _LR50% [A] ≧ λ _LR50% [B]
However,
T _{IRCF (600)} : spectral transmittance of light having a wavelength of 600 nm T _{IRCF (540)} : spectral transmittance of light having a wavelength of 540 nm λ _LT 50%: wavelength T _{IRCF (700} of near infrared light at which the spectral transmittance becomes 50% ₎ : Spectral transmittance λ _LR50% of light having a wavelength of 700 nm: wavelength of near-infrared light having a spectral reflectance of 50%
λ _{LR 50%} [A]: wavelength of near-infrared light at which the spectral reflectance at the surface facing the object side is 50%
[ lambda ] _{LR 50%} [B]: The wavelength of near-infrared light at which the spectral reflectance on the surface facing the image side is 50%, and the unit of wavelength is nm. The imaging device according to claim 16, wherein the plurality of lenses or lens groups is five. The imaging device according to claim 16, wherein the plurality of lenses or lens groups is six. The imaging device according to claim 16, wherein the plurality of lenses or lens groups is seven. The imaging device according to claim 16, wherein the plurality of lenses or the lens group includes a lens having a surface having an inflection point on the image side or the object side. The imaging device according to claim 20, wherein a lens having a surface having the inflection point is disposed closest to the image side among the plurality of lenses or lens groups. The imaging apparatus according to claim 21, wherein the inflection point is provided on an image side surface. The imaging apparatus according to claim 21, wherein the inflection point is provided on an object side surface. The imaging device according to claim 16, wherein the plurality of lenses or the lens group includes a lens having a convex shape and a concave shape on one surface. The imaging device according to claim 24, wherein the lens provided with the convex shape and the concave shape is disposed closest to the image side among the plurality of lenses or the lens group. The imaging device according to claim 25, wherein the convex shape and the concave shape are provided on an image side surface. The imaging device according to claim 25, wherein the convex shape and the concave shape are provided on an object side surface. A cover glass is provided on the object side of the image sensor,
The imaging device according to claim 16, wherein the optical element is disposed on the object side of the cover glass. The imaging device according to any one of claims 16 to 28, wherein the optical element has a larger image height than the imaging element. A signal processing unit,
The imaging device according to any one of claims 16 to 29, wherein the signal processing unit converts the output signal from the imaging device into a digital signal and performs image quality correction. The imaging device according to any one of claims 16 to 30, wherein the imaging device is a CMOS.

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