Abstract: A radiation image detecting system includes an image detecting information storing section storing thereon an image detecting condition under which a radiation image judged by a reader of the radiation image to be inappropriate is detected in association with a site whose radiation image is detected under the image detecting condition judged inappropriate, an image detecting information designating section designating, before a radiation image of an examined subject is detected, an image detecting condition under which the radiation image of the examined subject is detected and a site of the examined subject which is image-detected, and a warning section issuing an warning to a user when the image detecting condition designated by the image detecting information designating section falls within a predetermined range including an image detecting condition stored on the image detecting information storing section in association with the site designated by the image detecting information designating section.

Abstract: Apparatus and methods for therapy delivery are disclosed. In one embodiment, a therapy delivery system includes a plurality of movable components including a radiation therapy nozzle and a patient pod for holding a patient, a patient registration module for determining a desired position of at least one of the plurality of movable components, and a motion control module for coordinating the movement of the least one of the plurality of movable components from a current position to the desired position. The motion control module includes a path planning module for simulating at least one projected trajectory of movement of the least one of the plurality of moveable components from the current position to the desired position.

Abstract: The present invention provides system, devices, and methods for scanning an object while avoiding radiation exposure. For example, the present invention provides systems comprising a scanning device with input and output openings, and a safety sensor adjacent to the input or output opening that sends a signal that turns off or physically blocks electromagnetic radiation if the presence of an invading element (e.g., human hand) is detected by the safety sensor.

Abstract: Systems, methods, and other modalities are described for (a) obtaining an indication relating to an emission module (which may be dangerous, e.g.) or its user (who may be untrained, e.g.) and for (b) configuring the module or causing an irradiation (for imaging, e.g.) in response to the indication.

Abstract: Systems, methods, and other modalities are described for (a) obtaining an indication relating to an emission module (which may be dangerous, e.g.) or its user (who may be untrained, e.g.) and for (b) configuring the module or causing an irradiation (for imaging, e.g.) in response to the indication.

Abstract: In a method and system for monitoring the power state of an x-ray emitter and/or an x-ray detector, the x-ray emitter is operated according to a set of test parameters, so as to emit x-rays that strike at least a portion of the detector region of the x-ray detector. At least one value characterizing the operation of the x-ray emitter and/or the x-ray detector is determined, and this detected parameter is compared with a comparable reference parameter value. The power state of the x-ray emitter and/or the x-ray detector is determined based on deviation of the detected parameter from the reference parameter.

Abstract: A power supply for a device which has a load, comprising a first resonant generator and a second resonant generator, coupled in parallel, each generator having a phase output. The power supply further comprises a control circuit coupled to the first and second generators controlling the first and second phase outputs, wherein the first phase output and the second phase output are summed to provide a variable power supply to the load.

Abstract: A medical x-ray detection device includes an x-ray detector operable to detect the presence of x-ray radiation in a medical environment, and a signal emitter operatively coupled to said x-ray detector. The signal emitter includes at least one active light-emitting signal device, wherein the signal emitter is operative to emit a signal corresponding to the presence of x-ray radiation.

Abstract: The present invention is directed to a mobile X-ray apparatus having a main unit, a moving carriage for installing the main unit, a column standing on the moving carriage, an X-ray generator supported by the column, and an image reader for reading X-ray image information from an imaging plate in which the X-ray image information is stored. The X-ray apparatus is provided with a brake for putting a brake on the moving carriage, a brake control means for applying the brake or releasing the brake, a read control means for prohibiting reading by the image reader, while the brake control means releases the brake, a cassette loading slot for inserting a cassette enclosing the imaging plate into the image reader, a blocking member for closing at least a part of the cassette loading slot to block the cassette to be inserted, and an open and close control means for closing the blocking member to prevent insertion of the cassette while the read control means prohibits reading.

Abstract: A method and a device for optimizing the image display on imaging apparatuses register whether an operator is looking at the imaging apparatus. The image display of the imaging apparatus is optimized, when it is registered that the operator is looking at the imaging apparatus and namely by dimming the room lighting and/or by increasing the contrast of the imaging apparatus.

Abstract: A medical table wherein a top board on which a patient is placed is supported by a base having an internal instrument so as to be movable parallel to the board surface, the medical table includes a detecting device that detects the possibility that a hand or fingers, which grip the top board, come in contact with the internal instrument during the movement of the top board or internal instrument, and a preventing device that prevents the movement of the top board or the internal instrument on the basis of a detection signal of the detecting device.

Abstract: A method and system for auto positioning a compression mechanism in a mammography imaging system is disclosed herewith. The method comprises: automatically elevating the compression mechanism upon detection of a breast biopsy device. The breast biopsy device can be detected upon connecting the same to the mammography system or can be detected upon noticing the same on the vicinity of the mammography system. The compression mechanism includes: breast compressor, breast holding paddles and paddle holders.

Abstract: An online analysis device, including a feed conveyor for supplying material, an X-ray tube, having an X-ray beam directed toward a measuring range on a feed conveyor, a control unit for actuating the X-ray tube, an X-ray detector that measures the radiation that interacts with, or is emitted by, the material, and a material detector for detecting material in the measuring range and generating a signal dependent thereon. To omit a mechanical shutter without reducing the service life of the tube, the material detector is connected to the control device, which controls the X-ray tube in dependence on the signal from the material detector in one of two states, where the heating current for the X-ray tube has the same order of magnitude in both states and the acceleration voltage in the first state is 5 kV to 100 kV and in the second state is less than 10 kV.

Abstract: An X-ray CT apparatus includes an X-ray generator and an X-ray detector. The X-ray generator and the X-ray detector rotate about a subject. A controller controls the timing of exposing X-rays from the X-ray generator. The controller controls the collection timing for the projection data used by the X-ray detector and causes the X-ray detector to continuously collect the projection data at the specified collection timing. The controller causes additional information representing the state of exposure of the X-rays to be added to each projection data that has been collected by the X-ray detector at said specified collection timing.

Abstract: Systems, methods and apparatus are provided through which a safety switch arrangement is assembled to prevent false activation of a subsystem in a medical system. In some embodiments, the safety switching arrangement comprises at least a first and a second type of switching element. In some embodiments, the first and the second type of switch each have an output that is processed by a processor, controller, or logic unit to produce an output signal for activating or deactivating a subsystem in the medical system.

Abstract: A method, a system and a device for automated configuration of a high power X-ray source apparatus (10), which has multiple modules (20, 28, 30, 50, 53). A first module (20, 28, 30, 50, 53) of the high power X-ray source apparatus (10) has an identification unit (25, 27, 31, 52, 54) storing at least one parameter of the first module (20, 28, 30, 50, 53) and transmitting the parameters to a configuration control unit (60). At least one operating parameter of a second module (20, 28, 30, 50, 53) is determined by the configuration control unit (60) based on characteristics of the transmitted parameter of the first module (20, 28, 30, 50, 53). The high power X-ray source apparatus (10) is configured by setting the operating parameter of the second module (20, 28, 30, 50, 53) to the determined value.

Abstract: The present disclosure describes a self-contained irradiator comprising at least one X-ray source inside a shielded enclosure, the one or more sources each operable to emit X-ray flux across an area substantially equal to the proximate facing surface area of material placed inside the enclosure to be irradiated. The irradiator may have multiple flat panel X-ray sources disposed, designed or operated so as to provide uniform flux to the material being irradiated. The advantages of the irradiator of the present disclosure include compactness, uniform flux doses, simplified thermal management, efficient shielding and safety, the ability to operate at high power levels for sustained periods and high throughput.

Abstract: A diagnosis device, in particular an x-ray device, includes a patient couch which is rotatably mounted on a carrier device as well as a diagnosis unit, which is likewise mounted on the carrier device and can be moved along a longitudinal direction in parallel to the patient couch by a motor drive and an adjustment mechanism. A measuring device for measuring a measurement signal of a measured variable correlated with the drive force is provided in order to promptly identify a collision between the diagnosis unit and a patient mounted on the patient couch. A control unit is provided to evaluate the measurement signal. The control unit is designed in order to trigger a reaction when a predetermined value in respect of the measurement signal is exceeded.

Abstract: A system is in a standby mode as an imaging preparation condition in step S1. If gripping of an operation handle is detected in step S2, the operation goes to step S3, in which an electromagnetic brake is released, thereby allowing a radiation detector to be rotated substantially around the center of an imaging region. If a rotation angle is detected in step S5, a first limiting device covering an effective imaging region of the radiation detector is changed to a second limiting device so as to be constantly arranged within the effective imaging region even during rotation of the radiation detector.

Abstract: A portable radiographic imaging device includes an operation unit, a controller, and an execution unit. The operation unit is operated when a target function is selected from plural different functions relating to radiographic image capturing. When a first condition, that expresses that a predetermined region has been placed at a predetermined placement portion, is established, the controller carries out control such that a function that should be effective when the first condition is established is selected. When a second condition, that expresses that the predetermined region is not placed at the placement portion, is established, the controller carries out control such that a function that should be effective when the second condition is established is selected. When the operation unit is operated, the execution unit executes a function that is controlled by the controller to be selected.

Abstract: A medical imaging system includes a medical imaging device, a medical imaging control subsystem, and an activation unit. The medical imaging control subsystem includes a processing unit and a monitor. The processing unit is in communication with the medical imaging device and the monitor. The activation unit is operatively connected to the medical imaging device and the medical imaging control subsystem, wherein the activation unit is operable to deactivate the medical imaging device and the medical imaging control subsystem.

Abstract: A method and apparatus for reconstructing a body map of a patient that provide automatic control of speeds of moving parts of the apparatus, regulation of an x-ray dose, and computation of time of exposure to the x-ray dose.

Abstract: X-ray system with an x-ray radiation source, a digital solid-state image detector with a calibration facility acquiring calibration data in order to ensure an optimum image quality, whereby the x-ray system has at least one sensor or interacts with a sensor which detects any person who may be present in the vicinity, whereby the acquisition of the calibration data is initiated when no person has been detected by the at least one sensor.

Abstract: An integrated weight sensing system and method is disclosed for a medical imaging system. In one embodiment, the integrated weight sensing system may include a table assembly, a load cell, and a processor that are implemented in a medical imaging system. The table assembly includes a lifting mechanism used to position a patient within the medical imaging system. The load cell is mechanically coupled to the table assembly and in communication with the processor. The load cell is configured to measure and indicate the weight of the patient and the processor may be configured to adjust imaging parameters based on the weight of the patient. The table assembly may include a device in communication with the load cell and/or processor to display the weight of the patient. Additionally, the table assembly and/or the processor may include an interface for zeroing or recalibrating the load cell.

Abstract: A cooling unit is provided in a storage section to locally cool a heat generating portion of an imaging device and to thereby reduce nonuniformity of the distribution of the temperature in the imaging device. Detectors detect a mount orientation of the imaging device, that is, whether the imaging device is mounted in landscape orientation or portrait orientation. Cooling portions of the cooling unit are selectively driven on the basis of the detection result.

Abstract: A system and method to improve the high voltage performance of an x-ray tube with electrostatic deflection of an electron beam focal spot. The system and method provides protection of bias circuits from high voltage transients and spit protection in x-ray tubes through the use of a high voltage transient suppression and spit protection circuit assembly coupled between the bias circuits of a high voltage generator and an x-ray tube vacuum housing of an x-ray generation system.

Abstract: In a radiation imaging apparatus having a radiation generator, an imaging unit including a detecting unit for detecting radiation to generate a radiation imagedata, a carriage for carrying the radiation generator, and an operating unit for providing an interface to a user, it is decided whether the radiation imaging apparatus is in a moving state or not. When it is decided that the radiation imaging apparatus is in a moving state, the operation function of the operating unit for the radiation detector and the imaging unit is limited.

Abstract: An X-ray imaging apparatus includes an X-ray intensity designation unit which designates an emitted X-ray intensity of X-rays applied to a target, an X-ray exposure control unit which compares a predetermined recommended X-ray intensity with the emitted X-ray intensity designated by the X-ray intensity designation unit to determine whether the emitted X-ray intensity becomes equal to or more than the recommended X-ray intensity, and a warning generating unit which generates a warning signal indicating that the emitted X-ray intensity becomes equal to or more than the recommended X-ray intensity, on the basis of the determination made by the X-ray exposure control unit.

Abstract: The present invention is directed to a networked scanner environment wherein each scanner is communicatable with one or more databases configured to store data associated with previously executed imaging sessions. The one or more databases may be queried by a user to determine, based on a set of user inputs, an historical evaluation of the prior imaging sessions conducted in accordance with scan parameters similar to the scan parameters of an imminent imaging session. The present invention includes a global database that is accessible by a series of remotely located imaging systems as well as includes one or more databases particular to a specific treatment facility housing one or more imaging scanners. The present invention is also applicable with a stand-alone imaging system having a database local to that particular imaging system for storing and accessing data associated with imaging sessions conducted on that particular imaging system.

Abstract: The invention relates to an x-ray C-arm apparatus comprising an x-ray C-arm and a control facility that moves the x-ray C-arm in at least one rotational and/or translational degree of freedom depending on a control signal received. The x-ray C-arm apparatus features a user interface with a control element connected to the x-ray C-arm. The control element is connected to the user interface and enables it to be moved with at least one rotational and with at least one translational degree of freedom. The user interface detects the movement of the control element and creates the control signal depending on the movement of the control element, with the control signal representing at least the degree of freedom and/or a direction of movement of the control element, especially a direction of movement in the degree of freedom.

Abstract: A proximity detector employs a capacitive sensor, having: at least one detection antenna including numerous capacitive proximity sensors which each include a measuring electrode, the antenna being positioned close to an object or body; electronic elements for exciting the electrodes and processing the distance measurement signals originating from the capacitive sensors; and digital elements of controlling the electronic elements and of calculating the distances between the electrodes and the body or object using the processed measurement signals. The detection antenna also contains a single guard for all of the measuring electrodes. Moreover, the electronic elements have, for each detection antenna, a floating or floating excitation capacitive bridge which co-operates with polling elements in order sequentially to measure the respective capacitances between each electrode and the object or body to be measured.

Abstract: The detected positioning error in a geometry item of a radiotherapy apparatus is generally passed to a transfer function for the system, which outputs a signal that dictates the radiation output. If the detected error is within certain limits then the radiation is permitted whereas outside those limits it is not permitted; this corresponds to a transfer function that is a simple two step function. We propose a transfer function having a result that is (a) substantially zero outside a preset error tolerance, (b) has a maximum result at a point within that tolerance, and (c) has a result that is between zero and that maximum over a range of error values that lie between (i) the error value corresponding to the maximum output and (ii) the preset error tolerance. This means that if an error grows towards (but does not exceed) the error tolerance, the output of the radiation source will reduce and allow time for the geometry item to correct its position.

Abstract: The present invention involves an angiography device for examining vessels of patients having an x-ray emitter and an associated detector, having an image processing unit, an image display unit, a control unit, a collision computer and sensors. The sensors, which are fastened to the angiography device, are designed to scan the outer dimensions of the patient prior to the actual examination and during the examination. The data obtained in this way can be fed into a memory of the collision computer and the system is controllable by a software of the collision computer such that the movement of the system when the system and patient become too close can be automatically slowed down or completely stopped by means of a the control unit.

Abstract: An X-ray system for preventing X-ray leakage includes a sensor that detects an open/close state of a door of a room, a wireless transmitter that receives the open/close state of the door from the sensor and sends it out in a wireless manner, an X-ray device that emits X-rays, and a wireless receiver, which is provided on the X-ray device, that receives the open/close state from the wireless transmitter and sends it to the X-ray device, wherein the X-ray device controls whether or not to emit X-rays based on the open/close state received from the wireless receiver.

Abstract: The present invention refers to a radiation system (1) comprising an excentric gantry (100) arranged in connection with multiple treatment rooms (61-68) separated by radiation-shielding separating members (71-78). A movable rotation head (120) is connected to the gantry (100) and is able to move between, and direct a radiation beam (110) into, the treatment rooms (61-68). A simulator head (200-1 to 200-8) is preferably arranged together with the radiation system so it can be used in each respective treatment room (61-68). In such a case, while a first subject (40-1) is being irradiated in a first room (61), a treatment set-up procedure, including correct positioning of subjects (40-2 to 40-8) and irradiation simulation, can simultaneously take place for the other subjects (40-2 to 40-8) in the other treatment rooms (62 to 68).

Abstract: The detected positioning error in a geometry item of a radiotherapy apparatus is generally passed to a transfer function for the system, which outputs a signal that dictates the radiation output. If the detected error is within certain limits then the radiation is permitted whereas outside those limits it is not permitted; this corresponds to a transfer function that is a simple two step function. We propose a transfer function having a result that is (a) substantially zero outside a preset error tolerance, (b) has a maximum result at a point within that tolerance, and (c) has a result that is between zero and that maximum over a range of error values that lie between (i) the error value corresponding to the maximum output and (ii) the preset error tolerance. This means that if an error grows towards (but does not exceed) the error tolerance, the output of the radiation source will reduce and allow time for the geometry item to correct its position.

Abstract: Methods and systems for medical imaging are provided. The system includes a gantry assembly having a stator, a first rotor rotatably coupled to the stator, the first rotor configured to rotate about an examination axis at a first rotational speed, and a second rotor rotatably coupled to at least one of the stator and the first rotor, the second rotor configured to rotate about the examination axis at the first and a second rotational speed, the second rotational speed being greater than the first rotational speed, the first and second rotors configured to be locked in position with respect to each other during rotation at the first rotational speed, the first rotor configured to be locked in position with respect to the stator during rotation of the second rotor at the second rotational speed.

Abstract: A method includes thermally stabilizing a Computed Tomography (CT) detector module.

Abstract: In embodiments, x-ray apparatus for imaging a subject, the x-ray apparatus having a base assembly and an x-ray source supported by the base assembly, the x-ray source being operable for generating x-ray energy, the x-ray apparatus having a control system for controlling operation of the x-ray source, the x-ray apparatus including: a detector for detecting a monitored condition, the detector generating detector output; the control system receiving the detector output; and the control system including a portable visual indicator independent of the base assembly and portable in relation thereto, the portable visual indicator displaying a state of the monitored condition.

Abstract: The present invention relates to a collision detecting device for a radiation treatment apparatus, comprising a radiation unit having an internal space, for directing radiation beams towards a radiological focus in the internal space for treatment of a target in a patient's body therein. The collision detecting device comprises a collision detecting unit being electrically conductive at least on its outer surface and having a size slightly smaller than the internal space of the radiation unit, so as to be insertable into the internal space and held in an electrically insulating manner in respect of the radiation unit by spacer elements. The outer electrically conductive surface is connectible to an electrical voltage supply in order to detect if the outer surface of the collision detecting unit abuts against the inside surface of the radiation unit. The invention also relates to a method for performing such collision detection.

Abstract: This system for dental X-ray image acquisition comprises an X-ray generator and a control module for controlling an intra-oral sensor. The module includes means for sending a command to the generator in application of at least one predetermined criterion for preventing, stopping, or modifying the power of X-ray emission. The use of this system for optimizing the quantity of X-rays received by a patient.

Abstract: To comply with radiation protection provisions that differ from one another for different operating functions without operational restrictions, a radiation protection system is provided in the case of a multifunctional x-ray system for a solid state detector assigned to the x-ray system. The radiation protection system includes a device for restricting the current outer contours of an x-radiation field to bounding outer contours dependent on the selected operating function of the x-ray system.

Abstract: A method of detecting collisions between elements in a medical procedure such as between a magnet and another element in the procedure mounting on the medical device a flexible body within which is mounted one or more parallel side by side optical fibers arranged such that the impact causes bending of one or more of the optical fibers and detecting changes in light transmission through the optical fiber to detect the bending and thus the collision. The single fiber or fibers are located in a junction between a lower body of resilient foam and a surface layer of a stiffer flexible material.

Abstract: The invention relates to a medical imaging system as well as a collision protection method for such a system. In this system the movement of a moveable part, e.g. a C-arm, is stopped or slowed down, if the part enters an individual protective zone enclosing the patient. This zone is calculated individually for each patient from the surface of the patient detected by an optical sensor.

Abstract: An apparatus for controlling the transmission of electromagnetic radiation generated in a radiation generator is provided. The apparatus includes a printed circuit board having a substrate layer and at least one medium layer bound to the substrate layer. The printed circuit board is configured to control the transmission of the electromagnetic radiation.

Abstract: X-ray device with at least one switch for triggering a signal and at least one receiver for the signal are provided. The receiver may be arranged remote from the switch. The switch (6) includes an energy converter for converting the mechanical energy expended in the event of the switch being triggered into electrical energy. The signal can then be wirelessly transmitted to the receiver (15) by way of a radio link.

Abstract: Systems, methods and apparatus are provided through which a safety switch arrangement is assembled to prevent false activation of a subsystem in a medical system. In some embodiments, the safety switching arrangement comprises at least a first and a second type of switching element. In some embodiments, the first and the second type of switch each have an output that is processed by a processor, controller, or logic unit to produce an output signal for activating or deactivating a subsystem in the medical system.

Abstract: A method and system for detecting a collision state between various elements of an x-ray imaging apparatus and/or a patient when they occur and resolving the collision state by reversing the movement of the x-ray imaging apparatus along the same path traveled which led to the collision state in the first instance.

Abstract: The invention relates to a residual-current circuit breaker for an X-ray device. In one embodiment, the residual-current circuit breaker comprises at least one input, via which a detector identification signal of a detector identification element can be received, said signal characterizing the presence of an X-ray detector and at least one input, via which a selection signal for an exposure measurement element can be received, said signal characterizing the activation of an exposure measurement element. A deactivation signal can be issued via at least one output of the residual-current breaker, the deactivation signal being generated as long as a detector identification signal and a selection signal that is assigned to the same detector as the detector identification signal are not received at the same time.

Abstract: A status indication device configured for use in an x-ray system is disclosed. The device includes an audio receiver, a processor, a tone generator, and an adjustment mechanism. The audio receiver is configured and disposed to collect audio information surrounding the x-ray system. The processor is coupled to the audio receiver and receptive of a signal representative of the collected audio information. The tone generator is coupled and responsive to the processor and is configured to generate an audio tone in response to a defined status of the x-ray system. The adjustment mechanism is coupled to the tone generator and the processor and dynamically develops a set of audio properties that cause the audio tone to be distinguishable from the collected audio information.