Abstract: A phantom, adapted to be radiation-imaged to obtain a radiation image for evaluation in inspection of a radiation imaging system, is capable of performing both the quantitative evaluation and the visual evaluation of the radiation image easily with a low cost and increasing accuracy of the constancy evaluation of the radiation imaging system. The phantom includes a base plate; a first member disposed on the base plate and having a first image quality evaluating pattern formed thereon to be used for visual evaluation as to a predetermined image quality evaluation item; and a second member disposed on the base plate and having a second image quality evaluating pattern formed thereon to be used for quantitative evaluation as to the predetermined image quality evaluation item.

Abstract: Reference image signals representing at least two reference images of different phases of an object, whose phase varies within a predetermined variation range, are stored. Successive image recording operations are performed on the object, whose phase is varying within the predetermined variation range, with a low radiation dose and at predetermined time intervals, and successive recorded images are acquired. The phase of the object is detected for each of the successive recorded images and in accordance with the reference images of the different phases of the object. When the detected phase of the object coincides with a desired phase, an ordinary image recording operation with an ordinary radiation dose is performed.

Abstract: A mammography apparatus capable of obtaining a clear breast image with reduced burden on the subject. The apparatus includes a radiation irradiation section and an object table connected to an arm such that they face each other, and the breast pressed on the object table using a compression paddle is imaged by rotating the arm according to the imaging direction. In the apparatus, the size of the breast is detected, and the relative position between the radiation irradiation section and object table is changed along the side of the object table facing the chest wall of the subject according to the detected size of the breast and the direction of rotation of the arm.

Abstract: A mammography apparatus capable of obtaining a breast image having an optimum density with reduced burden on the subject. The apparatus includes a radiation irradiation section and an object table connected to an arm such that they face each other, and the breast compressed onto the object table using a compression paddle is imaged by rotating the arm by an arm rotation means according to the imaging direction. In the apparatus, the size of the breast is detected, and the position of a dose detector is moved along the side of the object table facing the chestwall of the subject according to the detected size of the breast and the angle of rotation of the arm when rotated by the arm rotation means.

Abstract: In a specimen analysis system: a light injection unit selectively injects unscattered light and scattered light into a specimen at an incident position on the specimen, and an information processing unit performs calculation of a characteristic of the specimen by diffusion approximation, where the calculation of the characteristic in a near-incident-point region located within a predetermined distance from the incident position is based on information carried by light which exits from the near-incident-point region of the specimen in response to injection of the scattered light into the specimen, and the calculation of the characteristic in a remote region located farther from the incident position than the near-incident-point region is based on information carried by light which exits from the remote region in response to injection of the unscattered light into the specimen.

Abstract: In a specimen analysis system: incident light is injected into a specimen at an injection position on the specimen; an information acquisition unit acquires first information carried by light exiting from each of positions in a first region of the specimen in response to injection of the incident light into the specimen for a first duration of measurement, and second information carried by light exiting from each of positions in a second region of the specimen in response to injection of the incident light into the specimen for a second duration of measurement longer than the first duration of measurement; and an information processing unit calculates a characteristic of the specimen on the basis of the first and second information. The first region is located within a predetermined distance from the injection position, and the second region is located farther from the injection position than the first region.

Abstract: A fluorescent image obtaining apparatus for obtaining as an image the data relating to the fluorescent light emitted from a measurement portion upon the irradiation thereof by an excitation light, wherein by amplifying only the intensity of the fluorescent light, the S/N ratio of the fluorescent image based thereon is improved, is provided. The statistical quantities of a fluorescent image obtained by a wide-band fluorescent image obtaining element and a narrow-band fluorescent image obtaining element are computed by a statistical quantity computing means. If the statistical quantity is smaller than a predetermined value, the magnification rate of the imaging optical system is controlled by a magnification rate control means so that the fluorescent image is reduced and focused on the wide-band fluorescent image obtaining element and the narrow-band fluorescent image obtaining element.

Abstract: A fluorescence detecting system includes a stimulating light projector which projects onto an object part which has been dosed with a fluorescence agent first stimulating light in the exciting wavelength range of the fluorescence agent and second stimulating light which differs from the first stimulating light in the wavelength band and is in the exciting wavelength range of the auto-fluorescence material contained in the object part, and a fluorescence information obtainer which obtains the fluorescence from the fluorescence agent information based on the fluorescence from the fluorescence agent emitted from the object part in response to projection of the first stimulating light and the auto-fluorescence information based on the auto-fluorescence emitted from the object part in response to projection of the second stimulating light. The fluorescence agent is a fluorescence agent which does not emit fluorescence in response to projection of the second stimulating light.

Abstract: A tomosynthetic image taking apparatus takes an x-ray image of an object in each of a plurality of positions of an x-ray source to obtain a desired tomogram of the object by adding up the x-ray images thus obtained. A heartbeat phase is detected and the tomosynthetic image taking apparatus is controlled to take an x-ray image of the object in each of the plurality of positions of the x-ray source when the heartbeat of the object is in the same heartbeat phase.

Abstract: A correction function is calculated based on a reference image formed of reflected light reflected upon the irradiation of a predetermined living tissue, for which a diseased state is known, with a reference light. This correction function is employed to administer distance correction on calculated standardized values based on fluorescence images to which an offset has been added, to correct the fluctuations of the calculated standardized values caused by the distance between living tissue and the distal end of a fluorescence endoscope, thereby generating a corrected standardized fluorescence image.

Abstract: First fluorescence diagnostic information reflecting a first characteristic value obtained on the basis of first fluorescence information on fluorescence emitted from an object part exposed to first stimulating light is output. Second fluorescence diagnostic information reflecting a second characteristic value obtained on the basis of second fluorescence information on fluorescence emitted from an object part exposed to second stimulating light is output. The wavelength of the first stimulating light is such that when the first stimulating light is projected onto clean object parts different in properties, different first characteristic values are obtained from the different object parts, and the wavelength of the second stimulating light is such that when the second stimulating light is projected onto a clean object part and an unclean object part, different second characteristic values are obtained from the clean object part and the unclean object part.

Abstract: A fluorescence observing apparatus including a light source for emitting excitation light, an excitation light irradiation section for irradiating the excitation light to a sample, and a fluorescence measurement section for measuring fluorescence emitted from the sample by the irradiation of the excitation light. In the fluorescence observing apparatus, a GaN semiconductor laser is employed as the light source.

Abstract: A fluorescence image display apparatus is provided; wherein, when a pseudo color image representing the tissue state of a target subject is obtained, based on a fluorescence image emitted from the target subject upon the irradiation thereof by an excitation light, the tissue state can be recognized regardless of the intensity of the fluorescent light. Based upon the statistical quantity of a wide band fluorescence image computed by a statistical quantity computing means, a gain that the wide band and narrow band fluorescence image data are to be multiplied by is computed by a gain computing means. A gain multiplying means multiplies the wide band and narrow band fluorescence image data by the gain, whereby a green gradation is assigned to the wide band fluorescence image and a red gradation is assigned to the narrow band fluorescence image, and a composite image data is obtained by an image composing means.

Abstract: A fluorescence image display apparatus is provided; wherein, when a pseudo color image representing the tissue state of a target subject is obtained, based on a fluorescence image emitted from the target subject upon the irradiation thereof by an excitation light, the tissue state can be recognized regardless of the intensity of the fluorescent light. Based upon the statistical quantity of a wide band fluorescence image computed by a statistical quantity computing means, a gain that the wide band and narrow band fluorescence image data are to be multiplied by is computed by a gain computing means. A gain multiplying means multiplies the wide band and narrow band fluorescence image data by the gain, whereby a green gradation is assigned to the wide band fluorescence image and a red gradation is assigned to the narrow band fluorescence image, and a composite image data is obtained by an image composing means.

Abstract: A radiation emission control method, apparatus and the program capable of detecting respiratory phases of a test subject with constant accuracy and emitting radiation rays to the test subject in synchronization with an intended respiratory phase, while minimizing the radiation exposure to the subject. A test subject having a contour that varies with the respiration is optically imaged continuously by the optical image obtaining section to sequentially obtain optical images of the subject, and respiratory phases of the subject are detected simultaneously with the optical imaging by the respiratory phase detecting section based on the contour of the subject on the optical images. During the optical imaging, a radiation source is controlled by the control section such that radiation rays are emitted to the test subject when the detected respiratory phase corresponds to an intended respiratory phase of the subject.

Abstract: Reference image signals representing at least two reference images of different phases of an object, whose phase varies within a predetermined variation range, are stored. Successive image recording operations are performed on the object, whose phase is varying within the predetermined variation range, with a low radiation dose and at predetermined time intervals, and successive recorded images are acquired. The phase of the object is detected for each of the successive recorded images and in accordance with the reference images of the different phases of the object. When the detected phase of the object coincides with a desired phase, an ordinary image recording operation with an ordinary radiation dose is performed.

Abstract: A plurality of past cross-sectional images are reconstructed from a plurality of past tomosynthesis images obtained by radiographing a subject by tomosynthesis. A plurality of current cross-sectional images are reconstructed from a plurality of current tomosynthesis images obtained by radiographing the subject by tomosynthesis. Each of the plurality of past cross-sectional images is superimposed on a corresponding current cross-sectional image included in the plurality of current cross-sectional images for each cross-sectional plane so as to align structural elements therein. When the structural elements are aligned, a subtraction image between the corresponding past cross-sectional image and current cross-sectional image is produced.

Abstract: Detection of the difference between images of the same subject obtained at different times is performed effectively. The cardiac phases of the subject are detected, and a current image is obtained through X-raying the subject at the time when the detected cardiac phase corresponds to that of the past image. Thereafter, a differential image is obtained from the current and past images by obtaining the difference between them.

Abstract: A method and apparatus for obtaining a dynamic radiographic image with enhanced resolution, in which an electrocardiogram of a subject is obtained, and five time phases are allocated to each cardiac beat period (1 second). The initial X-ray irradiation is performed at 1st time phase of 1st beat to obtain a radiographic image. Thereafter, X-ray irradiations are performed sequentially at 2nd time phase of 2nd beat, at 3rd time phase of 3rd beat, at 4th time phase of 4th beat, and at 5th time phase of 5th beat to obtain respective radiographic images. The five radiographic images obtained are combined at the time interval of 0.2 seconds to be displayed as a motion image. The time interval between the irradiations of the X-ray is 1.2 seconds, so that image signals corresponding to 1st to 5th time phases may be obtained with high resolution.

Abstract: A tomosynthetic image taking apparatus takes an x-ray image of an object in each of a plurality of positions of an x-ray source to obtain a desired tomogram of the object by adding up the x-ray images thus obtained. A heartbeat phase is detected and the tomosynthetic image taking apparatus is controlled to take an x-ray image of the object in each of the plurality of positions of the x-ray source when the heartbeat of the object is in the same heartbeat phase.