Abstract: There is provided an imaging device that includes an APD filter, and can accurately perform the determination of an imaging exposure and the detection of a focus position together. An imaging exposure is determined using a corrected diaphragm value (T number) obtained by correcting a diaphragm value on the basis of optical characteristics of the APD filter and an imaging diaphragm, which is determined during the determination of the imaging exposure, is set. After that, a search interval SD, by which a focus lens is moved for the time of auto-focusing, is determined using a diaphragm value (F number), which is not yet corrected, without using the corrected diaphragm value (T number). The search interval SD is set to a value that is calculated by dividing the product of the depth D of focus and a predetermined value C by an image plane movement coefficient k.

Abstract: An adsorbent, which can be produced by a method in which a particle size, a pore size, a specific surface area or the like can be easily controlled, and is suitable for isolation of biomolecules. The adsorbent contains aggregates of calcium phosphate-based particles, and has an average pore size of 15 to 36 nanometers and a specific surface area of 40 to 90 m2/mL when measurement is carried out by mercury porosimetry.

Abstract: In a state in which an APD filter is present on an optical axis of an imaging optical system, a digital camera sets the maximum movable amount of a focus lens to one side of an optical axis direction to a value that is less than that in a state in which the APD filter is not present on the optical axis of the imaging optical system and moves the focus lens in the range of the set maximum movable amount.

Abstract: An imaging device includes an APD filter. In a case in which the APD filter is disposed on a light path of an incident ray, an imaging exposure is determined using a corrected diaphragm value (T number) obtained by correcting a diaphragm value on the basis of optical characteristics of the APD filter and an imaging diaphragm, which is determined during the determination of the imaging exposure, is set. After that, a search interval SD is determined using a diaphragm value (F number), which is not yet corrected, in a first range in which the diaphragm value is larger than a specific value EF, without using the corrected diaphragm value (T number), and the search interval SD is determined by using the specific value as the diaphragm value in a second range in which the diaphragm value is equal to or smaller than the specific value EF.

Abstract: There is provided an imaging device that includes an APD filter, and can accurately perform the determination of an imaging exposure and the detection of a focus position together. An imaging exposure is determined using a corrected diaphragm value (T number) obtained by correcting a diaphragm value on the basis of optical characteristics of the APD filter and an imaging diaphragm, which is determined during the determination of the imaging exposure, is set. After that, a search interval SD, by which a focus lens is moved for the time of auto-focusing, is determined using a diaphragm value (F number), which is not yet corrected, without using the corrected diaphragm value (T number). The search interval SD is set to a value that is calculated by dividing the product of the depth D of focus and a predetermined value C by an image plane movement coefficient k.

Abstract: An imaging device includes an APD filter. A first program diagram is selected in a case in which the APD filter is not disposed, and a second program diagram is selected in a case in which the APD filter is disposed. A set of an imaging diaphragm value AV and an imaging shutter speed TV is determined on the basis of an exposure value obtained from a photometric value obtained from a photometric unit. The first program diagram is a multiple-stage diaphragm type program diagram. In the first program diagram, diaphragm values AV take discrete values at an interval of a first value. In the second program diagram, a part of corrected diaphragm values, which are obtained by correcting diaphragm values of the first program diagram on the basis of optical characteristics of the APD filter, are thinned out so that each interval has at least a second value.

Abstract: One embodiment shows a method for producing porous cellulose particles, including: (a) dissolving cellulose diacetate into a solvent to prepare a cellulose diacetate solution; (b) dispersing the cellulose diacetate solution into a medium immiscible with the cellulose diacetate solution to obtain a dispersed system; (c) cooling the dispersed system; (d) adding a poor solvent to the cooled dispersed system to precipitate cellulose diacetate particles; and (e) saponifying the cellulose diacetate particles.

Abstract: An object is to provide a method for producing an ever-larger molecular weight collagen-like polypeptide single strand. Another object is to provide a method for controlling a molecular weight of a product to be obtained in desired magnitude upon producing a collagen-like polypeptide single strand. A solution is a method for producing a polypeptide including a step for allowing a condensation reaction of peptide oligomers represented by any one of formulas (1) to (3) (SEQ ID No:1 to SEQ ID No:3), wherein the condensation reaction is carried out in an aqueous solvent containing a phosphate ion in the range of 0 M to less than 0.01 M in the presence of a condensing agent, or a condensing agent and a condensing auxiliary: H-(Pro-Y-Gly)n-OH??(1); H-(Y-Gly-Pro)n-OH??(2); and H-(Gly-Pro-Y)n-OH??(3); wherein, in formulas (1) to (3), Y is hydroxyproline or proline, and n is an integer from 1 to 10.

Abstract: An imaging method includes imaging light from an object passed through an imaging optical system to acquire a taken image, changing an imaging magnification of the imaging optical system, and switching a finder magnification of a finder optical system different from the imaging optical system from a first finder magnification to a second finder magnification when the imaging magnification increases and switching the finder magnification from the second finder magnification to the first finder magnification when the imaging magnification decreases.

Abstract: An imaging method includes imaging light from an object passed through an imaging optical system to acquire a taken image, changing an imaging magnification of the imaging optical system, and switching a finder magnification of a finder optical system different from the imaging optical system from a first finder magnification to a second finder magnification when the imaging magnification increases and switching the finder magnification from the second finder magnification to the first finder magnification when the imaging magnification decreases.

Abstract: During a period before focusing is instructed, contrast detection is used to detect positions at which focus evaluation values reach a peak in regard to detection regions obtained by dividing a region containing a region in which phase-difference detection pixels of an imaging element are disposed; when focusing is instructed, focus evaluation value peak positions of each of the detection regions are acquired; if an optical system is in a focused state, the number of detection regions whose deviation in focus evaluation value peak position is within a threshold value is counted; if the number of applicable detection regions is equal to or greater than a predetermined value, focus position detection and focus control are performed by phase-difference detection, and if the number of detection regions is less than the predetermined value, focus position detection and focus control are performed by contrast detection.

Abstract: An object is to provide a method for producing an ever-larger molecular weight collagen-like polypeptide single strand. Another object is to provide a method for controlling a molecular weight of a product to be obtained in desired magnitude upon producing a collagen-like polypeptide single strand. A solution is a method for producing a polypeptide including a step for allowing a condensation reaction of peptide oligomers represented by any one of formulas (1) to (3) (SEQ ID No:1 to SEQ ID No:3), wherein the condensation reaction is carried out in an aqueous solvent containing a phosphate ion in the range of 0 M to less than 0.01 M in the presence of a condensing agent, or a condensing agent and a condensing auxiliary: H-(Pro-Y-Gly)n-OH??(1); H-(Y-Gly-Pro)n-OH??(2); and H-(Gly-Pro-Y)n-OH??(3); wherein, in formulas (1) to (3), Y is hydroxyproline or proline, and n is an integer from 1 to 10.

Abstract: During a period before focusing is instructed, contrast detection is used to detect positions at which focus evaluation values reach a peak in regard to detection regions obtained by dividing a region containing a region in which phase-difference detection pixels of an imaging element are disposed; when focusing is instructed, focus evaluation value peak positions of each of the detection regions are acquired; if an optical system is in a focused state, the number of detection regions whose deviation in focus evaluation value peak position is within a threshold value is counted; if the number of applicable detection regions is equal to or greater than a predetermined value, focus position detection and focus control are performed by phase-difference detection, and if the number of detection regions is less than the predetermined value, focus position detection and focus control are performed by contrast detection.

Abstract: An imaging apparatus is equipped with: imaging means constituted by a great number of first light receiving elements and second light receiving elements that photoelectrically convert light from subjects, which are capable of being controlled to be driven independently form each other and are arranged in a predetermined arrangement, for obtaining image signals based on the output of the first light receiving elements and/or the second light receiving elements; image signal processing means, for generating image data from the image signals obtained by the imaging means; subject discriminating means, for discriminating subject scenes based on the image signals; subject field data obtaining means, for obtaining subject field data based on the image signals; and control means, for selecting a drive mode to drive the imaging means and the image signal processing means, based on the discriminated subject scenes and the obtained subject field data.

Abstract: (wherein Y1 and Y2 may be the same or different and each represents a hydrogen atom, halogen or lower alkyl; and Z and A may be the same or different and each represents substituted or unsubstituted aryl, or substituted or unsubstituted heteroaryl) The present invention provides, for example, a method for stabilization of a diarylvinylene compound such as a compound represented by the above formula (I) or the like, or a pharmaceutically acceptable salt thereof in a solid formulation containing the diarylvinylene compound or the pharmaceutically acceptable salt thereof, which comprises allowing an inorganic substance and/or a colorant to exist in the solid formulation, and the like.

Abstract: An imaging apparatus includes: an imaging optical system including a focus lens; an imaging element generates an image indicating an object image; a lens drive device which moves the focus lens along an optical axis direction of the imaging optical system; an evaluation value calculation device which calculates an evaluation value of a contrast for each of a plurality of evaluation value calculation areas while moving the focus lens; a point light source presence/absence determination device which determines a presence or absence of a point light source in a specific region of the image; an area selection device which selects a focusing determination area based on the presence or absence of the point light source; and a focusing control device which determines the focusing position of the focus lens based on the evaluation value in the focusing determination area and moves the focus lens to the focusing position.

Abstract: An imaging device including an image pickup device which converts an optical image of a photographic subject received through an imaging lens into an image signal; a displaying device which displays a through-the-lens image based on the image signal; a person detecting device which detects one or more persons from the image signal; a distance calculating device which calculates a distance between a plurality of the detected persons; and a composition assisting device which displays on the displaying device information as to whether the distance between the detected persons is proper or not based on the calculated distance between the detected persons. Thereby, it is possible to obtain an image with a proper composition in a case when there are a plurality of persons being the photographic subjects.

Abstract: A digital camera comprises two photographing systems which are independent of and substantially identical to each other, and each of which includes a photographing optical system and an image pickup device. The photographing optical system is configured to include a photographing lens, a focusing lens and an aperture stop. The focusing lens of one of the photographing systems is driven stepwise from a first predetermined position at which it is to be located when a focusing position lies at an infinite distance, toward a second predetermined position at which it is to be located when the focusing position lies at the closest distance, while the focusing lens of the other photographing system is driven stepwise from the second predetermined position toward the first predetermined position every step width.

Abstract: A photographing apparatus comprises a photographing device which photographs an image of an object; an illumination device which emits light at the photographing time and illuminates the object; a face detection device which detects a face area and a size of the face area of the person of the object from the image photographed by the photographing device; an object distance calculating device which calculates a distance up to the object from the size of the face area; a photographing sensitivity setting device that sets a photographing sensitivity according to the object distance; and a main emission control device which performs a main emission photographing by using the setting of the photographing sensitivity set by the photographing sensitivity setting device.

Abstract: An imaging apparatus includes: an imaging optical system including a focus lens; an imaging element generates an image indicating an object image; a lens drive device which moves the focus lens along an optical axis direction of the imaging optical system; an evaluation value calculation device which calculates an evaluation value of a contrast for each of a plurality of evaluation value calculation areas while moving the focus lens; a point light source presence/absence determination device which determines a presence or absence of a point light source in a specific region of the image; an area selection device which selects a focusing determination area based on the presence or absence of the point light source; and a focusing control device which determines the focusing position of the focus lens based on the evaluation value in the focusing determination area and moves the focus lens to the focusing position.