65results about How to "Overcome the influence of error" patented technology

A device for forming a dental prosthesis includes a support and an element which can be attached thereto, such as an impression element. The support has an anchoring part for anchoring in a bone or a master model, a shoulder with an annular shoulder surface, and a head. The impression element has an elastically deformable fixing agent. When the device is assembled, the fixing agent jams and / or latches with the support, either externally on the support, on the side of the shoulder facing the anchoring part, or in an axial hole of the support. The element can be quickly detachably connected to the support by placing it on top of the support, and can be quickly separated from the support by moving the support away. When the device is assembled, the support and the element can lay on top of each other with annular surfaces. The annular surfaces have fully circular outer edges which are visible from the outside in an approximately radial viewing direction.

A radiation therapy system comprises a magnetic resonance imaging (MRI) system combined with an irradiation system, which can include one or more linear accelerators (linacs) that can emit respective radiation beams suitable for radiation therapy. The MRI system includes a split magnet system, comprising first and second main magnets separated by gap. A gantry is positioned in the gap between the main MRI magnets and supports the linac(s) of the irradiation system. The gantry is rotatable independently of the MRI system and can angularly reposition the linac(s). Shielding can also be provided in the form of magnetic and / or RF shielding. Magnetic shielding can be provided for shielding the linac(s) from the magnetic field generated by the MRI magnets. RF shielding can be provided for shielding the MRI system from RF radiation from the linac.

In a reflection characteristic measuring apparatus 10 and a method for calibrating the reflection characteristic measuring apparatus, multiple standard spectral characteristics, or multiple calibration data based on the multiple standard spectral characteristics are obtained in advance with corresponding reference values relating to an emission characteristic of a light source 21. An optimum standard spectral characteristic or an optimum calibration data is selected from the multiple standard spectral characteristics or the multiple calibration data obtained. A spectral reflection characteristic of a sample is calculated using the selected standard spectral characteristic or the selected calibration data.

A radiation therapy system comprises a magnetic resonance imaging (MRI) system combined with an irradiation system, which can include one or more linear accelerators (linacs) that can emit respective radiation beams suitable for radiation therapy. The MRI system includes a split magnet system, comprising first and second main magnets separated by gap. A gantry is positioned in the gap between the main MRI magnets and supports the linac(s) of the irradiation system. The gantry is rotatable independently of the MRI system and can angularly reposition the linac(s). Shielding can also be provided in the form of magnetic and / or RF shielding. Magnetic shielding can be provided for shielding the linac(s) from the magnetic field generated by the MRI magnets. RF shielding can be provided for shielding the MRI system from RF radiation from the linac.

Disclosed herein is a color adjustment apparatus, including: a color information storage section configured to store color information regarding an arbitrary region designated through a pointer in an editing image region; and a color coordinate explicitly displaying section configured to explicitly display a mark, which specifies color coordinates corresponding to the color information, at a pertaining position on a hue ring or a hue bar chart prepared for color adjustment.

A device including an emitter that transmits light in a series of frames, wherein each frame in the series includes at least one pulse. The device includes a receiver that receives, for each frame in the series, the at least one pulse reflected from a target, and generates, in response to receiving the at least one pulse in a current frame, an output for calculating a distance between the target and the device for the current frame. The device includes circuitry that calculates, for each frame in the series, the distance between the target and the device based on the receiver output. The circuitry dynamically controls a frame rate for each frame in the series based on the distance calculated in a frame immediately preceding the current frame, and controls the emitter such that the at least one pulse is emitted in the current frame at the calculated frame rate.

A method for controlling an operation of a vapor compression system (VCS) determines values of measured outputs of the operation of the VCS that include performance and constrained outputs. The method determines states of the VCS using an estimator model of the VCS defining a relationship between the states of the VCS, control inputs and controlled outputs, such that a difference between outputs predicted using the estimator model and the measured outputs asymptotically approaches zero. The states of the VCS include a main state representing the operation of the VCS and an auxiliary state representing the effect of unknown disturbances on each measured output of the VCS. The control inputs for controlling the operation of the VCS are determined using a prediction model, such that the constrained output satisfies the constraints, and a difference between the performance output and the value of the setpoint asymptotically approaches zero.

In a reflection characteristic measuring apparatus 10 and a method for calibrating the reflection characteristic measuring apparatus, multiple standard spectral characteristics, or multiple calibration data based on the multiple standard spectral characteristics are obtained in advance with corresponding reference values relating to an emission characteristic of a light source 21. An optimum standard spectral characteristic or an optimum calibration data is selected from the multiple standard spectral characteristics or the multiple calibration data obtained. A spectral reflection characteristic of a sample is calculated using the selected standard spectral characteristic or the selected calibration data.

The invention relates to a physical model apparatus and a physical model apparatus method for simulating inclined rock stratums with different inclination angles. The physical model apparatus comprises a reaction force system, a loading system, a preparation system and a compaction system, wherein the reaction force device is formed by connecting a six-sided reaction force frame through high-strength bolts and supplies reaction force to the loading system, the loading system loads on a model material by using a hydraulic jack to simulate ground stress, the preparation system is used for holding and preparing the inclined rock stratum of the whole test, and the compaction system uniform compacts each layer of the similar material in the preparation system by the hydraulic jack of the loading system. According to the present invention, with the apparatus and the method, the physical model test of the horizontal rock stratum can be performed, the physical model tests of the inclined rockstratums with different inclination angles can be met, the influence of the artificial material spreading and compacting on the test result can be reduced, the layered compaction preparation of the inclined rock stratum is achieved, the influence of the test position does not exist, the requirements of different sites can be met, and the apparatus and the method can be used for large-scale three-dimensional physical model tests.

A conveyor belt tracking apparatus is provided for correcting the travel path of a laterally mistracking conveyor belt. In one form, an elongate tracking roller is rotatably mounted at end portions thereof to a pivotal support frame and extends across and below the belt. The pivotal support frame is mounted to a downstream pivot member so that belt mistracking toward one end portion of the tracking roller causes the one end portion to shift downstream and laterally outwardly to urge the belt toward the correct travel path. In one approach a downstream pivot connection between the pivot member and pivotal support frame is inclined upstream so that the end portion also shifts upwardly as it shifts downstream to urge the mistracking belt edge toward the correct travel path.

A PET apparatus is provided, which ensures excellent quantitativeness by properly correcting the influence of scattered radiation while improving the resolution of a reconstructed image and keeping good photon pair detection sensitivity. A determining section 52 determines whether a straight line connecting the light-receiving surfaces 15b of a pair of photon detectors 15a which have simultaneously detected a photon pair crosses any one of slice collimators 21n. When it is determined that the straight line crosses none of the slice collimators 21n, the corresponding coincidence counting information is accumulated by a first coincidence counting information storage section 53 to generate a signal sinogram. When it is determined that the straight line crosses one of the slice collimators 21n, the corresponding coincidence counting information is accumulated by a second coincidence counting information storage section 54 to generate a scatter sinogram. An image reconstructing section 60 corrects the influence of scattered components on the signal sinogram on the basis of the scattered sinogram, and reconstructs an image on the basis of the corrected signal sinogram.

The invention relates to a method and an X-ray detector (100) for detecting incident X-ray photons (X). The X-ray detector (100) comprises at least one sensor unit (105) in which X-ray photons (X) are converted into sensor signals (s) and at least one flux sensor (104) for generating a flux signal (f) related to the flux of photons (X). The sensor signals (s) are corrected based on the flux signal (f). In a preferred embodiment, the sensor signals (s) represent a spectrally resolved pulse counting. The flux sensor (104) may be integrated into an ASIC (103) that is coupled to the sensor unit (105).

With this position measurement method, a mark which has been formed upon an object is illuminated with an illumination beam, a beam which is generated from this mark is picked up via an observation system, and the resultant image signal is signal processed so as to measure positional information which is related to the mark. This signal processing is performed based upon information related to the noise which is included in the component dependent upon the amount of light which is included in the image signal, and upon said image signal. As a result, it is possible to measure the positional information for the mark with good accuracy, even if noise is included in the image signal.

A radiation-detecting device including at least two radiation detectors distributed in series along a support cable, each detector including an optically stimulated luminescence detection element which is optically coupled to at least one optical fiber, each optically stimulated luminescence detection element being held opposite a first end of the optical fiber by a mechanical part fixed to the support cable, the mechanical part being held in a flexible cable by a holding mechanism, second ends of each optical fiber leading to the same first end of the flexible cable.

In an optical head device, a birefringence correcting element 5a containing a material showing mono-axial refractive index anisotropy is located before an objective lens. The birefringence correcting element 5a is circumferentially divided into four regions by two straight lines passing through an optical axis and intersecting each other at right angle. Each of the four regions is radially divided into four sub-regions by three circles centered at the optical axis. The direction of optic axes of the sub-regions 11a to 14a and 11c to 14c is a direction of x-axis, while the direction of optic axes of the sub-regions 11b to 14b and 11d to 14d is a direction of y-axis. A phase difference of sub-regions between a polarized light component polarized in a direction parallel to the optic axis and another polarized light component polarized in a direction vertical to the optic axis increases in order of the sub-regions 11a to 11d, sub-regions 12a to 12d, sub-regions 13a to 13d and the sub-regions 14a to 14d.

A radiation computed tomography apparatus that includes a radiation detector having a plurality of radiation detector elements arranged in a two-dimensional manner for detecting radiation passing through a subject, and a reconstructing device for arithmetically reconstructing tomographic image data for a tomographic image of the subject based on projection data for the subject from each of the plurality of radiation detector elements, the projection data obtained from values detected by the plurality of radiation detector elements, wherein the reconstructing device corrects the projection data for each of the radiation detector elements using a corrective value that is correlated with a path length of the radiation through the subject calculated from the projection data, and generates the tomographic image data based on the corrected projection data.

In an X-ray computer tomograph and a method for investigating an object by means of X-ray computer tomography, to improve the image quality, a first intensity of the X-ray radiation between an X-ray source and the object is measured by means of a first intensity measurement device (13) and a second intensity of the X-ray radiation between the object and the X-ray detector outside a projection region of the object is measured by means of a second intensity measurement device. A scattered radiation correction factor is calculable by means of the measured intensities to reduce the scattered radiation.

In an image processing device such as an electronic camera having a detecting section which detects blurring of an image (movement of the image) picked up by an imaging element, a part of evaluation or calculation required for controls (AF, AE, AWB, etc.) is performed in parallel with the detection of the blurring of the image in order to speed up the controls. After completing the detection of the image blurring, an influence of the blurring is corrected to perform final calculation. In this case, an image area as a calculation object can be limited to raise a processing efficiency.

An optical pickup for recording a hologram by using an angle multiplexing method. An optical beam is separated into two beams, a signal beam and a reference beam having different convergence / divergence degrees, by using an optical component such as a diffraction lens. The signal and reference beams are made incident upon the same objective, and the optical component or the objective lens is moved in a direction perpendicular to an optical axis, to thereby realize angle multiplex recording. If an optical information recording medium is inclined, the optical component or the objective lens is moved along the direction along which the optical information recording medium moved to change an angle of the reference beam incident upon the optical information recording medium and compensate for degradation of a reproduction signal.

Provided is a method of quantifying a specific plant genus in a food or a food ingredient by a PCR method, comprising: (i) preparing a sample for correction where a sample derived from the specific plant genus to be detected and a standard plant sample are mixed in a predetermined ratio, and extracting genomic DNA from the sample for correction; (ii) preparing a test sample where a known amount of the standard plant sample is added to the food or the food ingredient to be examined, and extracting genomic DNA from the test sample; (iii) practicing a quantitative PCR method using the genomic DNAs and primers; and (iv) conducting correction with a standard value for correction determined for the sample for correction to calculate the amount of the specific plant ingredient contained in the test sample.

In front of the objective lens of an optical head deice, a birefringence correction element (5a) having a first birefringence correcting section consisting of a liquid crystal polymer layer (15a) and electrodes (14a, 14b), a second birefringence correcting section consisting of a liquid crystal polymer layer (15b) and electrodes (14c, 14d), and a third birefringence correcting section consisting of a liquid crystal polymer layer (15c) and electrodes (14e, 14f) is provided. The first birefringence correcting section corrects the impact of vertical birefringence of the protective layer in an optical recording medium variable depending on the kind of an optical recording medium, and the second and third birefringence correcting sections correct the impact of the recording medium protective layer in-plane birefringence that varies by the kind of the optical recording medium.

In order to provide high-quality image display by correcting and uniformizing the nonuniformity of electron emission characteristics, a predetermined arithmetic operation is performed by using correction values for correcting the nonuniformities of luminance caused by the electron emission devices when a predetermined voltage is applied thereto, thereby calculating correction values when the voltage having a plurality of voltage amplitude values is applied thereto. Corrected image data are calculated on the basis of the calculated correction values, and a drive signal is outputted to drive the electron emission devices on the basis of the corrected image data.

Machine control parameters of a magnetic resonance apparatus are selected that influence the timing sequence of gradient pulses of the system's gradient system when a magnetic resonance measurement sequence is executed. The machine control parameters are compared with reference control parameters that indicate an increased mechanical force flow in the gradient system when the MR measurement sequence is being executed. As a function of the comparison, the MR measurement sequence is executed selectively with the selected machine control parameters.

The invention relates to a method and an X-ray detector (100) for detecting incident X-ray photons (X). The X-ray detector (100) comprises at least one sensor unit (105) in which X-ray photons (X) are converted into sensor signals (s) and at least one flux sensor (104) for generating a flux signal (f) related to the flux of photons (X). The sensor signals (s) are corrected based on the flux signal (f). In a preferred embodiment, the sensor signals (s) represent a spectrally resolved pulse counting. The flux sensor (104) may be integrated into an ASIC (103) that is coupled to the sensor unit (105).