Systems and methods for modeling are provided. The method can include acquiring scan data associated with a plurality of x-ray projections of an item. The method can further include determining at least one closed boundary curve associated with the item. For example, the method can determine a first maximum area based on the scan data and determine at least one edge of the first maximum area. The method can further generate a model of the item using the closed boundary curve and a first material specific parameter for a material within the closed boundary curve. The method can utilize the model to generate computed scan data, compare the computed scan data to the scan data, and determine a goodness of fit. The method can further adjust the model of the item by altering at least one of the closed boundary curve and the material specific parameter.

The present disclosure provides a scanning bed control apparatus of medical imaging equipment. According to an example of the present disclosure, this scanning bed control apparatus comprises a support table and a drive mechanism connected between the support table and the scanning bed of medical imaging equipment. This drive mechanism comprises a drive motor, a central frame and a drive unit set on the central frame. Where, an output end of the drive motor is connected with a gear, and a rack joggled with the gear is fixed on the central frame. When the drive motor drives the central frame to move back and forth by joggle between the gear and the rack, the drive unit may proceed two-stage drive following the back and forth movement of the central frame.

A system for moving a patient into and from a medical apparatus includes a patient support arranged outside a treatment space of a medical apparatus, a treatment table arranged inside the treatment space in the medical apparatus and a patient bed movable in a longitudinal direction from the patient support to the treatment table and back by means of activation of a transferring mechanism. The patient bed is provided with at least a first communication channel for transferring communication signals.

A method automatically determines a weight of a patient lying on a tabletop of a patient positioning device. A motorized movement of the tabletop along at least one predeterminable axis sets the tabletop in an oscillation via an elastic drive train element, and the patient's weight is determined from a determined oscillation frequency. Therefore, the weight of a patient lying on a patient positioning device can be determined in a simple manner.

A device for transferring a subject in a medical procedure may be provided. The device may include a transmission assembly configured to transfer a subject to a scanning region of a medical device. The device may further include a supporting assembly supporting the transmission assembly. The supporting assembly may include at least one board and at least two supporting units supporting the at least one board. The at least two supporting units may be disposed at two sides of the scanning region of the medical device.

Provided is a backscattered X-ray image device based on multi-sources. The backscattered X-ray image device includes an X-ray tube array configured to generate X-rays, first slit plates provided on the X-ray tube array and having a first slit through which the X-rays pass, second slit plates provided on the first slit plates and having second slits defined in a direction different from that of the first slit, and detectors provided on the second slit plates and having a narrow gap in the same direction as the first slit, the detectors being configured to detect a backscattered beam that is emitted from a subject receiving the X-rays.

The present disclosure provides a scanning bed control apparatus of medical imaging equipment. According to an example of the present disclosure, this scanning bed control apparatus comprises a support table and a drive mechanism connected between the support table and the scanning bed of medical imaging equipment. This drive mechanism comprises a drive motor, a central frame and a drive unit set on the central frame. Where, an output end of the drive motor is connected with a gear, and a rack joggled with the gear is fixed on the central frame. When the drive motor drives the central frame to move back and forth by joggle between the gear and the rack, the drive unit may proceed two-stage drive following the back and forth movement of the central frame.

A cradle drive mechanism, a table and a patient imaging and carrying apparatus are provided. The cradle drive mechanism includes: a first portion, which is arranged on a main base and has a belt drive structure, wherein the belt drive structure is used to connect a cradle and drive the cradle to make a reciprocating motion; a second portion, which is arranged on a secondary base and has a secondary supporting and rotating member, wherein the second portion and the first portion form a gap therebetween, and the secondary supporting and rotating member is used to support the cradle; and two guiding and rotating members, which are arranged on the second portion and/or the first portion for guiding the cradle to move linearly. The present application can simplify the structure by adoption of the belt drive structure. Further, the gap between the second portion and the first portion does not attenuate the X-ray additionally, so the dose of the X-ray emitted can be decreased.