Abstract: Systems, processes and apparatus are described through which signals are modified within a system. A signal conditioning module is configured for insertion into the system and provides capability for expansion of information exchange capabilities between system elements responsive to modification of the system. The signal conditioning module includes a first link for supplying coordinated information to multiple display elements to synchronize information displayed by each of the multiple display elements, a second link for supplying coordinating data internal to a control system for a nondestructive imaging system to synchronize the internal data with the information displayed by each of the multiple elements and a third link for supplying coordination descriptions relevant to a nondestructive imaging task performed by the system to a memory, including an image and data relevant to that image.

Abstract: Embodiments provide apparatus for medical imaging which includes: a base assembly including a set of wheels for rolling movement on a floor to transport the base assembly between locations; an imaging assembly for imaging the subject; and a movable support assembly connected between the base assembly and the imaging assembly for supporting the imaging assembly on the base assembly and for extending and retracting the imaging assembly from the base assembly. Embodiments provide apparatus for medical imaging wherein overall length of the apparatus with the imaging assembly extended exceeds overall length with the imaging assembly retracted.

Abstract: In one embodiment, a braking system for a positioner unit in a medical imaging apparatus includes a first brake coupled to a drive unit that is configured to drive the positioner unit along an axis susceptible to influence of gravity. A second brake is coupled to the positioner unit, and configured for operating independently of the first brake. Examples of positioner unit include a patient cradle in a patient support table, and a C-arm and a pivot in a vascular gantry.

Abstract: A neonate imaging system is provided. The neonate imaging system includes a neonate magnetic resonance imaging system and a mobile neonate incubator system adapted for connection to the neonate magnetic resonance imaging system. The mobile neonate incubator system has an extendable and retractable carriage configured to shuttle the neonate between the mobile neonate incubator system and the neonate magnetic resonance imaging system. A neonate magnetic resonance imaging system is also provided. The neonate magnetic resonance imaging system includes a cylindrical magnet. The cylindrical magnet has a bore with dimensions that approximate dimensions of the neonate. A mobile neonate incubator system is further provided. The mobile neonate incubator system has an extendable and retractable neonate shuttling carriage.

Abstract: Systems, methods and apparatus are provided through which an impact absorbing material is affixed to a transportable device to protect the transportable device from impact with another object. In some embodiments, the impact absorbing material is a crumple zone material that has plastic deformation characteristics.

Abstract: Systems, methods and apparatus are provided through which in some embodiments, a medical imaging apparatus includes a medical image receptor, a wallstand, and a mechanism that provides at least 3 degrees of freedom. The mechanism is operably coupled to the medical image receptor and the mechanism is operably coupled to the wallstand.

Abstract: Systems and techniques are provided for a directional antenna system that employs a wireless link between x-ray apparatus. The system includes a host computer, an x-ray tube with an emission scan channel, a first directional antenna connected to the x-ray tube and with an orientation parallel to the emission channel, a second antenna wirelessly communicating with the first directional antenna, an x-ray detector wirelessly communicating with the x-ray tube, and a rigid panel supporting the second antenna and the x-ray detector being in contact with the emission scan channel. Specific techniques are employed to manage antenna direction and transmission.

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.