• Title of article

    Dosimetric investigation and portal dose image prediction using an amorphous silicon electronic portal imaging device

  • Author/Authors

    McCurdy، B. M. C. نويسنده , , Luchka، K. نويسنده , , Pistorius، S. نويسنده ,

  • Issue Information
    فصلنامه با شماره پیاپی سال 2015
  • Pages
    -910
  • From page
    911
  • To page
    0
  • Abstract
    A two step algorithm to predict portal dose images in arbitrary detector systems has been developed recently. The current work provides a validation of this algorithm on a clinically available, amorphous silicon flat panel imager. The high-atomic number, indirect amorphous silicon detector incorporates a gadolinium oxysulfide phosphor scintillating screen to convert deposited radiation energy to optical photons which form the portal image. A water equivalent solid slab phantom and an anthropomorphic phantom were examined at beam energies of 6 and 18 MV and over a range of air gaps (~20-50 cm). In the many examples presented here, portal dose images in the phosphor were predicted to within 5% in low-dose gradient regions, and to within 5 mm (isodose line shift) in high-dose gradient regions. Other basic dosimetric characteristics of the amorphous silicon detector were investigated, such as linearity with dose rate (±0.5%), repeatability (±2%), and response with variations in gantry rotation and source to detector distance. The latter investigation revealed a significant contribution to the image from optical photon spread in the phosphor layer of the detector. This phenomenon is generally known as "glare," and has been characterized and modeled here as a radially symmetric blurring kernel. This kernel is applied to the calculated dose images as a convolution, and is successfully demonstrated to account for the optical photon spread. This work demonstrates the flexibility and accuracy of the two step algorithm for a high-atomic number detector. The algorithm may be applied to improve performance of dosimetric treatment verification applications, such as direct image comparison, backprojected patient dose calculation, and scatter correction in megavoltage computed tomography. The algorithm allows for dosimetric applications of the new, flat panel portal imager technology in the indirect configuration, taking advantage of a greater than tenfold increase in detector sensitivity over a direct configuration.
  • Keywords
    Fault current limiter , short circuit current , transient over voltage , power quality
  • Journal title
    MEDICAL PHYSICS
  • Serial Year
    2001
  • Journal title
    MEDICAL PHYSICS
  • Record number

    1616