BIOMAT Database Logo BIOMAT Database Logo

A computer model of an image intensifier system working under automatic brightness control. 2001

A J Reilly, and D G Sutton
Department of Medical Physics, Ninewells Hospital and Medical School, Dundee DD1 9SY, UK.

A computer model of a fluoroscopy unit operating under automatic brightness control has been developed. The model has been validated by simulating one particular unit but is very general in nature and can easily be applied to other fluoroscopy systems. The model was developed by breaking the operation of a fluoroscopy unit down into its constituent parts then implementing each part in a module of code. It is controlled using the input air kerma to the intensifier face. Discrepancies from the situation when the model is controlled by the energy deposited in the input phosphor have been investigated and shown to be negligible over the operating range. To calculate entrance surface dose rates (ESDRs) to water and polymethylmethacrylate (PMMA) phantoms, Monte Carlo techniques were used to generate backscatter factors for these materials using the beam geometry and range of possible tube potentials and field sizes of a typical mobile image intensifier unit. The model was validated by calculating ESDRs to different thicknesses of water and PMMA phantoms. The predictions generated by the model were in good agreement with experimental measurements. Potential uses of the model include evaluation of dose reduction techniques, investigation of the balance between patient dose and image quality, and assessment of scatter dose.

UI MeSH Term Description Entries
D011829 Radiation Dosage The amount of radiation energy that is deposited in a unit mass of material, such as tissues of plants or animal. In RADIOTHERAPY, radiation dosage is expressed in gray units (Gy). In RADIOLOGIC HEALTH, the dosage is expressed by the product of absorbed dose (Gy) and quality factor (a function of linear energy transfer), and is called radiation dose equivalent in sievert units (Sv). Sievert Units,Dosage, Radiation,Gray Units,Gy Radiation,Sv Radiation Dose Equivalent,Dosages, Radiation,Radiation Dosages,Units, Gray,Units, Sievert
D011856 Radiographic Image Enhancement Improvement in the quality of an x-ray image by use of an intensifying screen, tube, or filter and by optimum exposure techniques. Digital processing methods are often employed. Digital Radiography,Image Enhancement, Radiographic,Radiography, Digital,Enhancement, Radiographic Image,Enhancements, Radiographic Image,Image Enhancements, Radiographic,Radiographic Image Enhancements
D003198 Computer Simulation Computer-based representation of physical systems and phenomena such as chemical processes. Computational Modeling,Computational Modelling,Computer Models,In silico Modeling,In silico Models,In silico Simulation,Models, Computer,Computerized Models,Computer Model,Computer Simulations,Computerized Model,In silico Model,Model, Computer,Model, Computerized,Model, In silico,Modeling, Computational,Modeling, In silico,Modelling, Computational,Simulation, Computer,Simulation, In silico,Simulations, Computer
D005471 Fluoroscopy Production of an image when x-rays strike a fluorescent screen. Fluoroscopies
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D000465 Algorithms A procedure consisting of a sequence of algebraic formulas and/or logical steps to calculate or determine a given task. Algorithm
D012542 Scattering, Radiation The diversion of RADIATION (thermal, electromagnetic, or nuclear) from its original path as a result of interactions or collisions with atoms, molecules, or larger particles in the atmosphere or other media. (McGraw-Hill Dictionary of Scientific and Technical Terms, 6th ed) Radiation Scattering,Radiation Scatterings,Scatterings, Radiation
D019047 Phantoms, Imaging Devices or objects in various imaging techniques used to visualize or enhance visualization by simulating conditions encountered in the procedure. Phantoms are used very often in procedures employing or measuring x-irradiation or radioactive material to evaluate performance. Phantoms often have properties similar to human tissue. Water demonstrates absorbing properties similar to normal tissue, hence water-filled phantoms are used to map radiation levels. Phantoms are used also as teaching aids to simulate real conditions with x-ray or ultrasonic machines. (From Iturralde, Dictionary and Handbook of Nuclear Medicine and Clinical Imaging, 1990) Phantoms, Radiographic,Phantoms, Radiologic,Radiographic Phantoms,Radiologic Phantoms,Phantom, Radiographic,Phantom, Radiologic,Radiographic Phantom,Radiologic Phantom,Imaging Phantom,Imaging Phantoms,Phantom, Imaging

Related Publications

A J Reilly, and D G Sutton
The siting of consistency checks on mobile image intensifier automatic brightness controls.
December 1994, The British journal of radiology,
A J Reilly, and D G Sutton
Statistical brightness gain of a channeltron image intensifier.
August 1968, Applied optics,
A J Reilly, and D G Sutton
[PNEUMOENCEPHALOGRAPHY UNDER CONTROL OF THE IMAGE INTENSIFIER].
November 1964, Der Nervenarzt,
A J Reilly, and D G Sutton
Image quality of an image-intensifier fluorographic system.
May 1984, Physics in medicine and biology,
A J Reilly, and D G Sutton
An automatic radiotherapy system with computer control.
February 1972, Radiography,
A J Reilly, and D G Sutton
Sensitivity of an image intensifier film system.
April 1966, Applied optics,
A J Reilly, and D G Sutton
Automatic collimation in fluoroscopy with image intensifier.
October 1965, Journal of the College of Radiologists of Australasia,
A J Reilly, and D G Sutton
Digital-holographic interferometry with an image-intensifier system.
February 2002, Applied optics,
A J Reilly, and D G Sutton
Automatic fringe analysis with a computer image-processing system.
July 1983, Applied optics,
A J Reilly, and D G Sutton
[Projection system with a brightness intensifier for biological and medical purposes].
January 1978, Doklady Akademii nauk SSSR,
Copied contents to your clipboard!