Abstract: Provided are a method for manufacturing an imaging-module and an imaging-module manufacturing device that can increase the flexibility of the component arrangement in an electronic device. A relative position of the lens unit and the imaging device unit, held on an axis perpendicular to a measurement chart, and the measurement chart on the axis is changed and images of the measurement chart are captured at the relative positions in the state where, when the lens unit is installed in an electronic device, a magnetic field having a magnitude equal to a magnitude of a magnetic field applied to the movable image-stabilizing unit is applied to the movable image-stabilizing unit. A compensation amount is calculated using signals acquired by capturing the images of the measurement chart, a tilt of the imaging device unit relative to the lens unit is adjusted, and the imaging device unit is fixed to the lens unit.

Abstract: Provided are a method for manufacturing an imaging module and an imaging-module manufacturing device that can enhance the flexibility of disposition of components in an electronic device. An amount of tilt by which and a direction of tilt in which a movable image-stabilizing unit is tilted in a state where a lens unit is installed in the electronic device including a magnetic-field generating unit are acquired in advance. On the basis of the amount of tilt by which and the direction of tilt in which the movable image-stabilizing unit is tilted, acquired in advance, the lens unit and the imaging device unit are fixed to each other in the state where an optical axis of the lens group is tilted by the amount of tilt in a direction opposite to the direction of tilt from a first reference position perpendicular to an imaging surface of the imaging device.

Abstract: The imaging lens includes a first lens group fixed during focusing and a positive second lens group moving to an object side during focusing from a long-distance object to a short-distance object, in order from a side closest to the object. The field curvature is adjusted by moving the first lens group or a sub-lens group within the first lens group including a lens closest to the object side, as an adjustment group. A stop fixed during the adjustment of the field curvature is disposed closer to an image side than the adjustment group. Conditional expressions relating to the focal length of the whole system, the focal length of the adjustment group, and the height of a paraxial on-axis light ray in the adjustment group are satisfied.

Abstract: The invention provides a dome cover for a camera and a camera with a cover that can effectively acquire an image in which a visually-recognizable range is wide and blurring is suppressed and that are durable. In one aspect of the invention, a dome cover (10) for a camera includes a curved section (11) of which a front surface and a back surface have a spherical shape; a skirt section (12) of which a front surface and a back surface have a cylinder shape; and a light-shielding part (15) that shields a part or whole of at least one of light that is incident from the skirt section (12) and is emitted from the curved section (11) or light that is incident from the curved section (11) and is emitted from the skirt section (12). The curved section (11) and the skirt section (12) are integrally molded.

Abstract: A camera apparatus (10) includes a degraded region information storage unit (24) that stores degraded region information for each direction in which degraded region data and an imaging direction are associated with each other, a direction recognition unit (30) that recognizes the imaging direction, and an image correction unit (32) that acquires degraded region data which is associated with the imaging direction recognized by the direction recognition unit (30) on the basis of the degraded region information for each direction and performs an image quality improvement process for the image data on the basis of a peculiar degraded region indicated by the degraded region data. The peculiar degraded region is a region related to a degradation element which is caused by at least one of the dome cover or the optical system and is based on at least one of a spatial frequency or signal intensity.

Abstract: A dome-type camera includes a dome cover (11) and a camera unit (12). The dome cover (11) has a front surface (21) and a back surface (22). The camera unit (12) includes an optical system (13) and an imaging element (14). The optical system (13) is disposed on the back surface (22) side of the dome cover (11), and the imaging element (14) outputs image data on the basis of imaging light received via the optical system (13). At least the back surface (22) out of the front surface (21) and the back surface (22) of the dome cover (11) has at least an aspheric shape in which optical properties are continuously changed at a location other than a top t of the dome cover (11).

Abstract: An imaging lens is constituted essentially by four or more lenses, including, in order from the object side to the image side: a first lens having a positive refractive power; a second lens having a negative refractive power; and a plurality of other lenses. The conditional formulae below are satisfied. 0.8<TL/f<1.0??(1) 1.0<f/fl<3.0??(2) 2.03 mm<f<5.16 mm??(3) 1.0 mm<fl<3.0 mm??(4) wherein f is the focal length of the entire lens system, fl is the focal length of the first lens, TL is the distance along the optical axis from the surface of the first lens toward the object side to the paraxial focal point position at the image side in the case that the portion corresponding to back focus is an air converted length.

Abstract: A method of manufacturing an optical element as defined herein, includes: coating, by an ink jet method, the part of the surface of the optical base member with an ink which contains a light blocking material containing the particles while sequentially shifting, by an interval of T, an area of the surface of the optical base member to be coated with the ink, to form the concave-convex shape of the light blocking layer on the part of the surface of the optical base member.

Abstract: Provided are a method for manufacturing an imaging-module and an imaging-module manufacturing device that can increase the flexibility of the component arrangement in an electronic device. A relative position of the lens unit and the imaging device unit, held on an axis perpendicular to a measurement chart, and the measurement chart on the axis is changed and images of the measurement chart are captured at the relative positions in the state where, when the lens unit is installed in an electronic device, a magnetic field having a magnitude equal to a magnitude of a magnetic field applied to the movable image-stabilizing unit is applied to the movable image-stabilizing unit. A compensation amount is calculated using signals acquired by capturing the images of the measurement chart, a tilt of the imaging device unit relative to the lens unit is adjusted, and the imaging device unit is fixed to the lens unit.

Abstract: Provided are a method for manufacturing an imaging module and an imaging-module manufacturing device that can enhance the flexibility of disposition of components in an electronic device. An amount of tilt by which and a direction of tilt in which a movable image-stabilizing unit is tilted in a state where a lens unit is installed in the electronic device including a magnetic-field generating unit are acquired in advance. On the basis of the amount of tilt by which and the direction of tilt in which the movable image-stabilizing unit is tilted, acquired in advance, the lens unit and the imaging device unit are fixed to each other in the state where an optical axis of the lens group is tilted by the amount of tilt in a direction opposite to the direction of tilt from a first reference position perpendicular to an imaging surface of the imaging device.

Abstract: An imaging lens is constituted essentially by four or more lenses, including, in order from the object side to the image side: a first lens having a positive refractive power; a second lens having a negative refractive power; and a plurality of other lenses. The conditional formulae below are satisfied. 0.8<TL/f<1.0??(1) 1.0<f/fl<3.0??(2) 2.03 mm<f<5.16 mm??(3) 1.0 mm<fl<3.0 mm??(4) wherein f is the focal length of the entire lens system, fl is the focal length of the first lens, TL is the distance along the optical axis from the surface of the first lens toward the object side to the paraxial focal point position at the image side in the case that the portion corresponding to back focus is an air converted length.

Abstract: An optical element includes an optical base material and a light blocking portion. The optical base material transmits light therethrough. The light blocking portion is formed on part of a surface of the optical base material. The light blocking portion includes a light blocking layer and an antireflection layer that is formed on a non-adhesion surface with the optical base material in the light blocking layer. A refractive index of the antireflection layer is lower than a refractive index of the light blocking layer.

Abstract: A focus extending optical system has optical lenses and a focus extender. The optical lenses form an image of light, from an object, on an image sensor. The focus extender adjusts a wavefront so as to change a position of the image, formed by the optical lenses, in accordance with a distance from an optical axis and thereby extends a focus range. The focus extending optical system satisfies a condition that a value of a second MTF is less than or equal to three times a value of a first MTF. The first MTF is an MTF at a spatial frequency of ½ of a Nyquist frequency of the image sensor. The second MTF is an MTF at a spatial frequency of ¼ of the Nyquist frequency.

Abstract: A focus extending optical system has optical lenses and a focus extender. The optical lenses form an image of light, from an object, on an image sensor. The focus extender adjusts a wavefront so as to change a position of the image, formed by the optical lenses, in accordance with a distance from an optical axis and thereby extends a focus range. The focus extending optical system satisfies a condition that a value of a second MTF is less than or equal to three times a value of a first MTF. The first MTF is an MTF at a spatial frequency of ½ of a Nyquist frequency of the image sensor. The second MTF is an MTF at a spatial frequency of ¼ of the Nyquist frequency.

Abstract: An image pickup apparatus according to one aspect of the invention includes: an imaging lens configured to perform a phase modulation function to extend a depth of field; a color image pickup element configured to convert an optical image which passes through the imaging lens and is formed on the image pickup element into an electric signal, the image pickup element having primary filters of three primary colors arranged for respective pixels in a predetermined pattern; and a restoration processing device configured to perform filtering processing using a single restoration filter on color signals corresponding to the primary filters of the three primary colors outputted from the color image pickup element, the restoration filter being an inverse function of a point spread function obtained when the phase modulation is performed by the imaging lens.

Abstract: The spherical aberration of an imaging lens changes from an object side of image-plane base position Zo toward the other side thereof as a distance from optical axis Z1 increases, and formulas 0.02<a/f<0.10 and 0.02<b/f are satisfied. In an imaging apparatus to which the imaging lens is applied, a blur is corrected by performing contrast recovery processing on original image data obtained by imaging. In the formulas, a is the magnitude of spherical aberration from the image-plane base position Zo toward the object side thereof affecting a ray passing through a central part of the pupil of the imaging lens, and b is a sum of a maximum spherical aberration from the image plane base position Zo toward the object side thereof and a maximum spherical aberration from the image plane base position Zo toward the other side thereof, and f is the focal length of the imaging lens.

Abstract: An image pickup apparatus according to one aspect of the invention includes: an imaging lens configured to perform a phase modulation function to extend a depth of field; a color image pickup element configured to convert an optical image which passes through the imaging lens and is formed on the image pickup element into an electric signal, the image pickup element having primary filters of three primary colors arranged for respective pixels in a predetermined pattern; and a restoration processing device configured to perform filtering processing using a single restoration filter on color signals corresponding to the primary filters of the three primary colors outputted from the color image pickup element, the restoration filter being an inverse function of a point spread function obtained when the phase modulation is performed by the imaging lens.

Abstract: The spherical aberration of an imaging lens changes from an object side of image-plane base position Zo toward the other side thereof as a distance from optical axis Z1 increases, and formulas 0.02<a/f<0.10 and 0.02<b/f are satisfied. In an imaging apparatus to which the imaging lens is applied, a blur is corrected by performing contrast recovery processing on original image data obtained by imaging. In the formulas, a is the magnitude of spherical aberration from the image-plane base position Zo toward the object side thereof affecting a ray passing through a central part of the pupil of the imaging lens, and b is a sum of a maximum spherical aberration from the image plane base position Zo toward the object side thereof and a maximum spherical aberration from the image plane base position Zo toward the other side thereof, and f is the focal length of the imaging lens.

Abstract: A phase correction plate is mounted on an imaging lens. The phase correction plate is structured in such a manner that the phase difference of light that has passed a middle region of the phase correction plate is lower than the phase difference of light that has passed a peripheral region of the phase correction plate, and that in the peripheral region, the phase difference of light that has passed through the phase correction plate increases from the middle-region side of the peripheral region toward the periphery side of the peripheral region.

Abstract: A backlight unit, comprising plural linear light sources, and an optical functional sheet, wherein a prism structure having plural prisms is formed on at least one surface of the optical functional sheet, and the values of (Hn?1+Hn)/(An?An?1) are approximately equivalent, wherein, in a brightness distribution graph that expresses a brightness distribution in the optical functional sheet, A1 is a peak site and H1 is a peak height of a first virtual image, A2 is a peak site and H2 is a peak height of a second virtual image adjacent to the first virtual image, . . . , An is a peak site and Hn is a peak height of (n)th virtual image adjacent to (n?1)th virtual image, and these virtual images are derived from the plural linear light sources.