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.

Abstract: Certain embodiments of the present invention provide a method for providing power to an x-ray imaging system including: sensing an electrical signal from a second power source; and routing the electrical signal from the second power source through at least one switch to an x-ray imaging system in response to the sensing an electrical signal from the second power source, wherein the at least one switch is capable of routing an electrical signal from at least one of: a first power source and the second power source. In an embodiment, the method further includes communicating a feature lockout signal to the x-ray imaging system in response to the sensing the electrical signal from the second power source. In an embodiment, the method further includes detecting the status of a safety sensor before routing the electrical signal from the second power source through the at least one switch.

Abstract: In a method and apparatus for generation of a digital x-ray image of an examination subject with an x-ray tube and a digital x-ray detector, a preliminary total dose required for correct exposure is determined using prior knowledge and a complete pre-image of the examination subject is acquired with a partial dose that is smaller than the preliminary total dose. A remaining dose is determined from the pre-image by image evaluation. A complete following image is acquired with this remaining dose, and the final x-ray image is assembled from the pre-image and the following image.

Abstract: A method of testing a portable x-ray device includes sensing an environmental stimulus experienced by the portable x-ray device, transmitting a signal related to the environmental stimulus to a processing unit, determining whether the signal meets an alert threshold, activating a detector of the portable x-ray device if the signal meets the alert threshold, producing a gray image through the activating step, comparing the gray image produced through the activating step with a control gray image corresponding to a properly functioning detector.

Abstract: In a radiation imaging apparatus having a radiation generator, an imaging unit including a detecting unit for detecting radiation to generate a radiation image data, 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 arm of an x-ray system is controlled with the aid of a joystick. If there is a threat of a collision between the x-ray arm and an obstacle, for example a patient bed, a force is exerted on the guide element which generates a warning signal perceptible in a tactile manner, which indicates to the user the danger of a collision.

Abstract: In a method for estimating the remaining life span of an X-ray radiator that has been installed in an X-ray apparatus and is operational, under specified test conditions and at time intervals, a measurement value that is indicative for the remaining life span of the X-ray radiator is determined and stored in a memory. A forecasted progression of future measurement values is then forecasted from the instantaneous measurement value and previous measurement values that were determined under identical test conditions, which also are stored in the memory. The forecasted remaining life span of the X-ray radiator is then determined based on the forecasted progression and a limit value that is associated with the individual X-ray radiator, which is stored in the memory.

Abstract: A method of providing an automatic protocol assistance includes determining a number of exposures for a scan of an object, acquiring a low dose AEC exposure of the object or acquiring at least one of a PA and an AP view, calculating an initial technique, and automatically determining whether to use the initial technique to perform the scan or to not perform the scan.

Abstract: A fluoroscope includes an x-ray generator, an x-ray tube for focusing the x-rays onto an area of a patient being imaged, and a fluoroscope monitor with a display screen for viewing the image captured by the fluoroscope. An on-demand multiple step fluoroscope control assembly includes a foot control and a head control. The foot control is operatively connected to the fluoroscope and adapted for being manually actuated by a foot of an operator. The foot control defines a first step activator for controlling activation of the x-ray generator. The head control is operatively connected to the fluoroscope and adapted for being automatically actuated when the operator views the display screen. The head control defines a second step activator for controlling activation of the x-ray generator. Upon simultaneous employment of the first and second step activators, the foot control and the head control cooperate to activate the x-ray generator and output radiation to the patient.

Abstract: A patient positioning system for use with a radiation therapy system that monitors the location of fixed and movable components and pre-plans movement of the movable components so as to inhibit movement if a collision would be indicated. The positioning system can also coordinate movement of multiple movable components for reduced overall latency in registering a patient. The positioning system includes external measurement devices which measure the location and orientation of objects, including components of the radiation therapy system, in space and can also monitor for intrusion into the active area of the therapy system by personnel or foreign objects to improve operational safety of the radiation therapy system.

Abstract: Systems, processes and apparatus are described through which non-destructive imaging is achieved, with equivalent or increased contrast, in comparison to conventional approaches, and that facilitate reduced dosage of X-rays delivered to the object or patient being imaged.

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: A collision detecting device includes a damper which is a hollow member with a fluid sealed into the interior thereof, and is formed, on its side abutted against an object to which it is to be mounted, in a concave shape conforming to the shape of a corner of the object, and is formed, on its side opposite to the concave shape, in a convex shape conforming to the shape of the corner of the object; and a detecting section for detecting an internal pressure of the damper.

Abstract: Systems and methods are provided for managing power consumption of a medical imaging detector by the use of triggering signals, environmental condition data, and/or determination of a variable time interval triggering event that is unique for each power consumption state. Systems and methods are provided for managing power and temperature of a device, after receiving a request for a function to be performed by the device determining an “on” trigger component, an “off” trigger component, associated circuits for performing the received function, providing power to the associated circuits upon the occurrence of the “on” trigger component, and removing power to the associated circuits upon the occurrence of the “off” trigger component. Further, an instruction is described for determining and displaying a variable time interval that is indicative of a time to change from one state to a desired state.

Abstract: An active dose radiation device and method decreases the amount of x-rays which may be generated by an x-ray tube following termination of the x-ray exposure. One component of the x-ray system is connected to the device which has a plurality of electronic cells that can be overvoltaged from a first state, where they are less conductive, to a second state, where they are highly conductive. A voltage pulse generator overvoltages a first cell in the plurality of cells at termination of an x-ray exposure. Overvoltaging the first cell causes a cascading effect which eventually overvoltages all of the cells and changes the state of the cells from the first less conductive state to the second highly conductive state. In the second highly conductive state, the cells can conduct current from at least one component of the x-ray system to ground thereby reducing x-rays generated by the x-ray tube and reducing the x-ray dosage from the imaging system after the x-ray exposure has been completed.

Abstract: A medical imaging system including an imaging device and a patient positioning area in close proximity to the imaging device. A protective bumper is attached to, and conforms to a shape of the imaging device. The system may also include a detection system that has a pressure sensing device.

Abstract: An X-ray imaging apparatus includes a body unit including a bed unit where an object is put, an X-ray irradiation unit configured to irradiate an X-ray to the object and an X-ray detector configured to detect the X-ray passing through the object, an input unit configured to input control information to control at least part of operation of the body unit, a selection unit configured to select ON or OFF of a lock mode and a controller configured to determine at least part of the control information is locked when the lock mode is ON and the at least part of the control information is released when the lock mode is OFF.

Abstract: A motor-adjustable X-ray system comprises a C-arm, which has two degrees of freedom and is adjustable with a motor support. The motor support has a force pickup device which is provided to detect a force exerted by an operator when manipulating the C-arm. The force pickup device is configured to detect a plurality of directional components of the exerted force and to cooperate with an evaluation unit, by which as a function of the plurality of the directional components of the exerted force, different amounts of motor support of the C-arm in the two degrees of freedom are established via the evaluation unit.

Abstract: The radiographic X-ray device according to this invention is constituted in such a way that positional relation detecting unit 25 detects in real time the information regarding the positional relations between X-ray imaging systems 4 and 8 that thoroughly represents the overall current status of the positional relations of external surfaces of both X-ray imaging systems 4 and 8 where collisions between first and second X-ray imaging systems 4 and 8 may occur, that the information regarding the positional relations detected by positional relation detecting unit 25 is taken into consideration in controlling the motions of X-ray imaging systems 4 and 8, and that the current status of the positional relations of external surfaces of both X-ray imaging systems 4 and 8 can be thoroughly and accurately reflected upon the motions of X-ray imaging systems 4 and 8 without any difficulty, so that any collisions of X-ray imaging systems 4 and 8 can be avoided without fail.

Abstract: The invention relates to a method and a device for automatic testing of an X-ray system (2). The doors (5a, 5b) leading to the room (1) in which the X-ray system (2) is installed are monitored by way of sensors (4a, 4b). Furthermore, the state of the room (1) can be monitored by means of further sensors such as video cameras (3). Automatic testing of the X-ray system (2) while utilizing X-rays is started only if and for as long as all doors are closed and the other sensors do not indicate that a safe state is abandoned. The device may also include facilities for automatically positioning a phantom in the beam path. Such facilities may in that case include a phantom which is provided on a flexible foil.

Abstract: A method and system of electronically detecting and measuring gravitational loads placed on an x-ray detector is disclosed. An x-ray detector incorporates an accelerometer that detects and provides an output as to the extent of gravitational loads or forces placed thereon. The accelerometer may also time and/or date stamp each recorded event such that a technician may determine when the x-ray detector was subjected to a particular load. A microcontroller/microprocessor may also compare a current reading of the accelerometer to a threshold and, based on the comparison, provide an audio or visual indication that the x-ray detector has been subjected to a potentially damaging gravitational load.

Abstract: A technique is provided for improving performance of a digital detector system, such as in a digital X-ray system. Improved frame rates and enhanced resolutions are achieved by selecting a field of view of interest and processing pixel information only for the selected field of view. Data from a series of rows of the detector are simultaneously processed by restoring charge to pixels of a row, while digitizing signals from a previously recharged row, and transmitting digital signals for a third row for which the signals were previously digitized. Scrubbing of rows outside the selected field of view may be performed as signals are detected and processes for rows within the selected field of view.

Abstract: A method for preventing an emission head or arm assembly from entering an exclusion zone or for preventing a collision between an object and the emission head and/or arm assembly. The method may include modeling a treatment room using a computer-aided design (CAD) tool, and calculating an exclusion zone for a radiosurgery system in the treatment room using the modeled treatment room.

Abstract: A method for preventing an emission head or arm assembly from entering an exclusion zone. The method may include calculating a variable dimension exclusion zone of a radiosurgery system, and preventing at least one of the emission head or arm assembly from entering the variable dimension exclusion zone. The method may also include establishing a exclusion zone of a radiosurgery system, the radiosurgery system comprising an x-ray source having an emission head, moving the emission head during treatment of a patient, wherein the exclusion zone travels with the emission head, and detecting a presence and location of an object in the traveling exclusion zone.

Abstract: An X-ray system, comprises a motor-adjustable C-arm, an input device which has a first actuating device and is mechanically connected to the C-arm, a dead man's switch, which is mechanically connected to the C-arm, and a pattern recognition module which cooperates with the input device and the dead man's switch, and is provided to determine a classification of actuating signal patterns generated via the first actuating device. A first signal group is activatable when the dead man's switch is actuated, and a second signal group is activatable when the dead man's switch is not actuated.

Abstract: The present invention provides a radiosurgery and/or radiotherapy x-ray system including a collision avoidance subsystem for detecting and avoiding obstacles during treatment. The system includes an x-ray source having an emission head at a distal end of an articulated arm assembly extending from a base unit, with the head being adapted for selectively emitting an x-ray beam along a beam axis, and including an associated controller for selectively orienting the head whereby the beam extends along a succession of treatment axes. The system further includes a collision avoidance subsystem including means for preventing the head and arm assembly from effecting a collision with an object in one or more pre-computed exclusion zones.

Abstract: A method and system of electronically detecting and measuring gravitational loads placed on an x-ray detector is disclosed. An x-ray detector incorporates an accelerometer that detects and provides an output as to the extent of gravitational loads or forces placed thereon. The accelerometer may also time and/or date stamp each recorded event such that a technician may determine when the x-ray detector was subjected to a particular load. A microcontroller/microprocessor may also compare a current reading of the accelerometer to a threshold and, based on the comparison, provide an audio or visual indication that the x-ray detector has been subjected to a potentially damaging gravitational load.

Abstract: Certain embodiments of the present invention provide a proximity detector having a simple configuration and an imaging system including the proximity detector. In an embodiment, a proximity detector mainly comprises: a single electrode mounted on a subject-side end of a movable member; a current feeding device for feeding a constant current to an electrostatic capacitor formed between the electrode and a ground; a discharging device for releasing charge from the electrostatic capacitor at intervals of a certain cycle; a binary-coding device for binary-coding the potential at the electrode relative to a ground based on a threshold; and a smoothing device for smoothing an output signal of the binary-coding device.

Abstract: There is disclosed a radiographic apparatus comprising a top plate for supporting a subject, an image receiver for receiving a radiographic image of the subject, a vertical moving mechanism for vertically moving the top plate and the image receiver, and means for limiting the action of the vertical moving mechanism according to the position relative to the top plate and/or posture of the image receiver. There is also disclosed a radiographic apparatus comprising a top plate for supporting a subject, an image receiver for receiving a radiographic image of the subject, a moving mechanism for varying the position relative to the top plate and/or posture of the image receiver, and means for limiting movement of the top plate in the predetermined direction in case the posture of the image receiver is not horizontal or limiting change in posture of the image receiver according to the position of the top plate.

Abstract: A radiographing apparatus, is provided which includes a control section and a plurality of radiographing sections, each of which is connected to the control section. The control section establishes a standby mode in each of the radiography sections when each of the plurality of radiographing sections has been unused for a period of time which exceeds a predetermined time period.

Abstract: In a method and apparatus for controlling an X-ray device having at least one X-ray tube and at least one X-ray detector, wherein the X-ray tube and/or the X-ray detector are movably arranged, before an activation of an X-ray tube indicated for a desired measurement, an automatic check is made out as to whether an X-ray detector indicated for the desired measurement is activated. Position data of the appertaining X-ray tube and/or appertaining X-ray detector are also automatically determined and using the identified position data, the relative positions of the appertaining X-ray tube and of the appertaining X-ray detector relative to one another are identified. The X-ray tube is enabled for activation, or is automatically activated, only when the X-ray detector is activated and the X-ray tube and the X-ray detector are suitably positioned relative to one another for the desired measurement.

Abstract: A method and system for reducing radiation exposure from an imaging system including determining an entry location, operating the imaging system so as to cause the imaging system to emit radiation having a radiation intensity, controlling the radiation intensity in a manner responsive to the entry location so as to create image data and processing the image data so as to create processed image data. In an alternative embodiment, a medium encoded with a machine-readable computer program code for reducing radiation exposure from an imaging system, the medium including instructions for causing a controller to implement the aforementioned method.

Abstract: The invention relates to a display and a control element for a control device for an X-ray unit. The triggering of an X-ray shot can be blocked automatically upon reaching a thermal loading limit for an X-ray source, where the display can display a period of time which the X-ray source requires in order to leave the thermal loading limit again. The triggering of an X-ray can be unblocked by operating the control element despite the thermal loading limit having been reached. In line with the invention, the display and the control element are integrated in a common break-time key.

Abstract: A beamblock tray for use with multiple defining heads within a medical linear accelerator is disclosed. The beamblock tray comprises a tray portion, and a plurality of coded connectors coupled to the tray portion that make the tray “intelligent” enough to identify its orientation to a user. The tray portion can be inserted into the defining head in a plurality of directions based upon the plurality of coded connectors. A system and method in accordance with the present invention utilizes a plurality of coded connectors that can be used to identify a patient. In addition, the connectors and a mounting flange are such that they permit the tray to be inserted in a plurality of directions. Finally, a coding system is provided that prevents radiation from being delivered if the tray is oriented incorrectly.

Abstract: The present invention is, in one embodiment, a method for efficiently and reliably communicating button presses electronically on a network from one or more push button nodes each having at least one push button, to a master node. This method includes steps of: generating status messages indicative of a push button states at each of push button node; communicating the status messages to the master node via the network; determining, at the master node, the state of the push buttons at each of the push button nodes from the communicated status messages; and triggering a response of the master node, in accordance with the statuses of the push buttons determined from the communicated status messages.

Abstract: In a method and apparatus for controlling an X-ray device having at least one X-ray tube and at least one X-ray detector, wherein the X-ray tube and/or the X-ray detector are movably arranged, before an activation of an X-ray tube indicated for a desired measurement, an automatic check is made out as to whether an X-ray detector indicated for the desired measurement is activated. Position data of the appertaining X-ray tube and/or appertaining X-ray detector are also automatically determined and using the identified position data, the relative positions of the appertaining X-ray tube and of the appertaining X-ray detector relative to one another are identified. The X-ray tube is enabled for activation, or is automatically activated, only when the X-ray detector is activated and the X-ray tube and the X-ray detector are suitably positioned relative to one another for the desired measurement.

Abstract: In order to reproduce the past operations of a medical system, a reproduction test service apparatus stores a plurality of past log files directly or indirectly supplied from the medical system in a log file storage unit and reproduces the past operations of the medical system on a pseudo X-ray CT system in accordance with the stored log files.

Abstract: A beamblock tray for use with multiple defining heads within a medical linear accelerator is disclosed. The beamblock tray comprises a tray portion, and a plurality of coded connectors coupled to the tray portion that make the tray “intelligent” enough to identify its orientation to a user. The tray portion can be inserted into the defining head in a plurality of directions based upon the plurality of coded connectors. A system and method in accordance with the present invention utilizes a plurality of coded connectors that can be used to identify a patient. In addition, the connectors and a mounting flange are such that permits the tray to be inserted in a plurality of directions. Finally, a coding system is provided that prevents radiation from being delivered if the tray is oriented correctly.

Abstract: An x-ray system 20 includes an x-ray tube insert (24) that has an evacuated envelope (34), an anode assembly (38) and a cathode assembly (40). The anode assembly (38) and the cathode assembly (40) are located in operative relationship to one another within the evacuated envelope (34). A temperature indicating member (100) is located in thermally conductive contact with at least one assembly (38, 40, 66) located in the x-ray tube insert (24). The temperature indicating member (100) has a temperature sensitive characteristic which changes in response to adequate thermal exposure to at least one temperature threshold value.

Abstract: A method and apparatus are provided for assessing performance of an imaging system. The imaging system has a performance assessment apparatus that comprises a system performance computer configured to execute a performance assessment algorithm. The performance assessment computer is coupled to receive signals from the detector assembly of the imaging array in a plurality of imaging system operating modes so as to identify disparities between actual system performance and nominal system performance for respective ones of the imaging system operating modes and to provide respective system performance output signals.

Abstract: A portable X-ray fluorescence analyzer has a measurement head section and an operating section. An X-ray source is disposed in the measurement head section for irradiating X-rays onto a sample for analysis of the sample utilizing principles of X-ray fluorescence. A power source is disposed in the operating section for supplying a voltage to the X-ray source to irradiate X-rays. A control circuit controls the power source to supply a voltage to the X-ray source through a first X-ray switch disposed in the measurement head section and a second X-ray switch disposed in the operating section by ON/OFF control of the first and second X-ray switches. A safety switch is disposed in the measurement head section for interlocking the first and second X-ray switches so that the control circuit controls the power source to supply a voltage to the X-ray source to irradiate X-rays only when the safety switch and the first and second X-ray switches are switched to an ON state.

Abstract: In an image collecting system for sensing an X-ray image by using a solid state image pickup unit, the operability of the system is improved by omitting an operation of turning on and off the solid state image pickup unit or other operations. When an operator selects an image sensing part of an object by using an acquisition part setting button on a display unit, the solid state image pickup unit is driven and a timer starts, and in addition, the sensing condition, image processing parameters and the like are automatically set in accordance with the selected sensing part. When an exposure button is depressed before the timer counts up, e.g., in 10 minutes, an X-ray generation control unit makes an X-ray tube radiate an X-ray to the object, and the solid state image pickup unit senses an X-ray image. If the exposure button is not depressed in 10 minutes, the operation of the solid state image pickup unit is stopped and the set sensing part is released.

Abstract: An X-ray computed tomography apparatus includes an X-ray tube configured to emit X-rays, an X-ray detector configured to detect X-rays passing through a subject in order to acquire projection data, a processor configured to reconstruct tomographic image data on the basis of the projection data, and an interlock unit configured to monitor generation of an arc in the X-ray tube. When an arc in the X-ray tube is detected, the interlock unit stops emitting X-ray emission from the X-ray tube. When a predetermined period of time elapse from the stop of X-ray emission, the interlock unit restarts X-ray emission from the X-ray tube.

Abstract: A medical apparatus for (radiation) diagnosis or therapy can be provided with moving parts 6. Such an apparatus must be provided with a collision detection device 26, 28, 30. A known collision sensor measures the supply current for the drive motor and hence induces a high degree of inaccuracy in the collision detection. According to the invention the force applied to the moving part (image intensifier 6) is measured directly on the relevant part so as to be compared with an expected value, an alarm signal being generated when a threshold value for the difference is exceeded. The expected value is calculated while taking into account all movement and acceleration parameters of the apparatus. The expected values can be calculated in advance and stored in a look-up table or can be calculated, preferably while using a model of the apparatus, during operation of the apparatus.

Abstract: The invention concerns an x-ray tube having a thermionic emitter and a warning means, which exhibits means for measuring as least one electrical property of the thermionic emitter and produces a signal during analysis of the measured electrical property, if the measured electrical property shows a value indicating an impending failure of the thermionic emitter.

Abstract: An apparatus for medical diagnosis and/or therapy is provided with an electromagnetic object sensor in order to prevent collisions between movable parts and, for example, a patient to be examined. The sensor may be provided with sensor electrodes 16 and 18 for capacitive detection of obstacles. In order to extend the area of sensitivity of the sensor electrodes in such a manner that it encloses the area in front of the X-ray entrance window 20 of the image intensifier 6, an additional electrode is provided in the beam path between the X-ray source 4 and the image intensifier, which additional electrode is coupled to sensor electrodes 18. The additional electrode includes a carrier which is provided with a thin metal layer, both being transparent to X-rays. The additional electrode may be subdivided into sectors 28-1, . . . , 28-4 which correspond to sectors 18-1, . . . , 18-4 of the sensor electrode in such a manner that the position of an obstacle relative to the image intensifier can be determined.

Abstract: In a method and a load computer for calculating the space-time temperature distribution in or, on an anode bombarded with electrons in an x-ray tube. The brief-term temperature boost in a surface layer in and around a focus spot on the anode of the x-ray tube is thereby calculated for the time span during and immediately after the electron bombardment of the focal spot, being calculated by the load computer. The load computer then calculates the long-term temperature distribution in the entire volume of the anode, taking into consideration the heat propagation that emanates from the focal spot as well as the heat emission from the surface of the anode. The results of the two calculations are added for determining the temperature distribution on and in the anode and, are displayed at a display and/or are, employed for driving the x-ray tube.

Abstract: A cooling system for use in conjunction with rotating anode and stationary anode x-ray tubes. The cooling system includes a reservoir containing a volume of coolant in which a portion of the x-ray tube is immersed. A bladder incorporated in the reservoir and in communication with the atmosphere automatically permits thermal expansion of the coolant while maintaining the coolant at atmospheric pressure. An external cooling unit directs a flow of coolant through a pressure drop device proximate to the x-ray tube so that the flowing coolant removes heat from the x-ray tube. Upon exiting the pressure drop device, the heated coolant is directed to the reservoir and ultimately returned to the external cooling unit where heat is removed from the coolant and the coolant then redirected back to the pressure drop device to repeat the cycle.

Abstract: This invention provides an X-ray CT apparatus which can be mounted in a motor vehicle, trailer, or container, including locking mechanisms for locking at least some of the movable portions of the X-ray CT apparatus, detectors for detecting the locking/unlocking states of the locking mechanisms, and a notifying unit for representing the states of the locking mechanisms on the basis of outputs from the detectors. Collision of an unlocked movable portion with its periphery during traveling can be avoided.

Abstract: Possible failure of x-ray tubes is predicted by monitoring and analysis of operating parameters considered leading indicators of failure. Historical data for a tube population is analyzed by discriminant analysis to develop a failure prediction algorithm. The algorithm is used to correlate operating parameters, or values derived from the operating parameters with a potential for tube failure. The operating parameters may include anode overcurrent events and spits, or spit rate exceeded errors for a diagnostic system in which the x-ray tube is installed.