Imaging simulation for integrated handheld X-ray transmission and backscatter imaging system with a disk scanner.

X-ray imaging technology can be divided into transmission and backscatter according to the signal receiving method, both are widely used security technology. In scenarios where it is not easy to utilize large equipment, there is a need for integrated handheld X-ray transmission and backscatter imaging equipment. Existing handheld integrated imaging devices often only add transmission signal receivers to handheld backscatter devices, and their transmission imaging capabilities are insufficient. In order to explore whether integrated handheld X-ray imaging equipment can be further optimized, a disk scanner for handheld X-ray integrated imaging system was designed and imaging simulation was performed. To improve the inadequate transmission capability of existing handheld X-ray machines, the transmission performance is strengthened by setting up transmission windows, which is capable of performing both flying line transmission and flying spot backscattering, overcoming the disadvantage of the existing equipment that can only use flying line scanning or flying spot scanning only. A dynamic simulation imaging method is developed to study the feasibility of the system, which includes the ray source simulation, the scanning process simulation, and the imaging simulation. The disk scanner with windows designed for the handheld X-ray transmission and backscattering integrated imaging system greatly enhances the transmission capability by sacrificing the backscattering capability through the addition of a window structure, and has a core advantage in the penetration resolution test. Its performance is evaluated by simulating the final imaging through the simulation of backscatter spatial resolution test, backscatter line resolution test, transmission resolution test and transmission penetration resolution test items. • The physical processes of X-ray transmission and backscattering were simulated. • A simulation model was designed based on realistically accessible equipment. • The simulated images of some standard objects irradiated by a continuous spectrum X-ray source are given. • The simulation has been set to perform on several tests. • A dynamic simulation imaging method is developed to study the feasibility of the system. [ABSTRACT FROM AUTHOR]