Abstract: Certain embodiments of the present invention provide an improved system and method for image file header configuration. Certain embodiments of the method include retrieving one or more criterion for configuration of an image orientation parameter, configuring the image orientation parameter based on the one or more criterion, obtaining image data, and storing the image data in an image file. The image file has a header portion including the image orientation parameter. In an embodiment, the image orientation parameter may be modified from a default configuration. The one or more criterion may include user preference, modality restriction, system preference, and/or rule, for example. The method may further include saving the image file with the configured image orientation parameter. Additionally, the method may include displaying an image according to the configured image orientation parameter. The image may be automatically oriented for display based on the configured image orientation parameter.

Abstract: Certain embodiments of the present invention provide an improved system and method for image file header configuration. Certain embodiments of the method include retrieving one or more criterion for configuration of an image orientation parameter, configuring the image orientation parameter based on the one or more criterion, obtaining image data, and storing the image data in an image file. The image file has a header portion including the image orientation parameter. In an embodiment, the image orientation parameter may be modified from a default configuration. The one or more criterion may include user preference, modality restriction, system preference, and/or rule, for example. The method may further include saving the image file with the configured image orientation parameter. Additionally, the method may include displaying an image according to the configured image orientation parameter. The image may be automatically oriented for display based on the configured image orientation parameter.

Abstract: Certain embodiments of the present invention provide an improved system and method for image file header configuration. Certain embodiments of the method include retrieving one or more criterion for configuration of an image orientation parameter, configuring the image orientation parameter based on the one or more criterion, obtaining image data, and storing the image data in an image file. The image file has a header portion including the image orientation parameter. In an embodiment, the image orientation parameter may be modified from a default configuration. The one or more criterion may include user preference, modality restriction, system preference, and/or rule, for example. The method may further include saving the image file with the configured image orientation parameter. Additionally, the method may include displaying an image according to the configured image orientation parameter. The image may be automatically oriented for display based on the configured image orientation parameter.

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 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: A detector for a portable imaging system includes a flash memory including a full set of configuration parameters and calibration files. The detector also includes a transmit and receive unit for communicating with the portable imaging system. The detector still further includes a detector controller responding to a request for identification of the detector received through the transmit and receive unit. The detector transmits calibration data and configuration data from the flash memory to the portable imaging system and boots the detector.

Abstract: Systems, methods and apparatus are provided through which the presence of a portable detector in a parking mechanism of mobile digital radiography system is used to change the operating mode of the portable detector and a mobile X-Ray system. An existing mobile digital X-Ray imaging system may be retrofitted with parking sensor mechanism for determining the proximity of the portable detector to the mobile digital radiography system. Also provided is a method for controlling a mobile digital imaging system having a mobile X-Ray base and having a parking mechanism for holding a detachable detector. Upon detecting the presence of the detachable detector in the parking mechanism a control signal is generated to alter the speed of the mobile unit and the power consumption status of the detachable detector.

Abstract: A method is provided for determining source-to-image distance (SID) setpoints in a digital imaging system. SID setpoints are determined during a setup and calibration procedure which includes generating radiation beams while varying certain system parameters, such as the radiation source position, and detecting and determining the size of the radiation beams that impact on the digital detector. SID values and a separation gain constant can then be determined based on the calculated sizes of the detected radiation beams and the feedback signals which are representative of the various system parameters that were varied (e.g., source position, etc.) during the setup and calibration procedure. The separation gain constant and the calculated, empirical SID values can then be used to position the radiation source at any user-selected SID based on position sensor feedback signals. The procedure also provides for a calibrated readout of the SID, which can be displayed to a user of the imaging system.

Abstract: In an X-ray imaging system, an arrangement is provided for readily aligning the system detector with the X-ray beam field, i.e., the projection of the X-ray beam into the plane of the detector. The arrangement is adapted for correcting or compensating for distortion which results from X-ray beam angulation, wherein the beam is projected toward the detector plane at an angle of less than 90°. Initially, the system X-ray tube is positioned to project the X-ray beam at a given beam direction angle &phgr;. A beam width angle &ggr;1 is then computed, from the given angle &phgr; and from specified values of the source-to-image distance and the length of the projected beam field. Thereupon, an offset value is determined from &ggr;1, &phgr; and the source-to-image distance to locate the geometric center of the beam field, and the center of the detector is aligned therewith.

Abstract: A method is provided for determining source-to-image distance (SID) setpoints in a digital radiographic imaging system. SID setpoints are determined during a setup and calibration procedure which includes generating x-ray beams while varying certain system parameters, such as the x-ray source position or the size of the collimator opening, and detecting and determining the size of the x-ray beams that impact on the digital detector. SID values and a separation gain constant can then be determined based on the calculated sizes of the detected x-ray beams and the feedback signals which are representative of the various system parameters that were varied (e.g., source position, collimator blade position, etc.) during the setup and calibration procedure. The separation gain constant and the calculated, empirical SID values can then be used to position the x-ray source at any user-selected SID based on position sensor feedback signals.

Abstract: A method is provided for automatically determining a variable laterally centered setpoint for a digital radiographic imaging system that includes a radiation source and a digital detector. The variable laterally centered setpoint is determined during a setup procedure which involves providing a detector at a detector location, positioning the radiation source at a first source location, detecting a radiation field generated by the source while at the first source location, determining the lateral centerline of the detected radiation field, repositioning the source to a second source location that is laterally displaced from the first location, detecting a second radiation field, and determining the lateral centerline of the second radiation field. A lateral gain constant for the imaging system can then be determined based on the determined centerlines of the first and second radiation fields and feedback signals from position sensors that are representative of the first and second source locations.