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Measuring linac photon beam energy through EPID image analysis of physically wedged fields
Author(s) -
Dawoud S. M.,
Weston S. J.,
Bond I.,
Ward G. C.,
Rixham P. A.,
Mason J.,
Huckle A.,
Sykes J. R.
Publication year - 2014
Publication title -
medical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.473
H-Index - 180
eISSN - 2473-4209
pISSN - 0094-2405
DOI - 10.1118/1.4856075
Subject(s) - linear particle accelerator , calibration , optics , beam (structure) , quality assurance , wedge (geometry) , dosimetry , range (aeronautics) , laser beam quality , photon energy , physics , nuclear medicine , photon , mathematics , materials science , statistics , medicine , laser , pathology , laser beams , external quality assessment , composite material
Purpose: Electronic portal imaging devices (EPIDs) have proven to be useful tools for measuring several parameters of interest in linac quality assurance (QA). However, a method for measuring linac photon beam energy using EPIDs has not previously been reported. In this report, such a method is devised and tested, based on fitting a second order polynomial to the profiles of physically wedged beams, where the metric of interest is the second order coefficient α . The relationship between α and the beam quality index [percentage depth dose at 10 cm depth (PDD 10 )] is examined to produce a suitable calibration curve between these two parameters.Methods: Measurements were taken in a water‐tank for beams with a range of energies representative of the local QA tolerances about the nominal value 6 MV. In each case, the beam quality was found in terms of PDD 10 for 100 × 100 mm 2 square fields. EPID images of 200 × 200 mm 2 wedged fields were then taken for each beam and the wedge profile was fitted in MATLAB 2010b (The MathWorks, Inc., Natick, MA). α was then plotted against PDD 10 and fitted with a linear relation to produce the calibration curve. The uncertainty in α was evaluated by taking five repeat EPID images of the wedged field for a beam of 6 MV nominal energy. The consistency of measuring α was found by taking repeat measurements on a single linac over a three month period. The method was also tested at 10 MV by repeating the water‐tank crosscalibration for a range of energies centered approximately about a 10 MV nominal value. Finally, the calibration curve from the test linac and that from a separate clinical machine were compared to test consistency of the method across machines in a matched fleet.Results: The relationship between α and PDD 10 was found to be strongly linear (R 2 = 0.979) while the uncertainty in α was found to be negligible compared to that associated with measuring PDD 10 in the water‐tank (±0.3%). The repeat measurements over a three month period showed the method to be reasonably consistent (i.e., well within the limits defined by local QA tolerances). The measurements were repeated on a matched machine and the same linear relationship between α and PDD 10 was observed. The results for both machines were found to be indistinguishable across the energy range of interest (i.e., across and close to the thresholds defined by local QA tolerances), hence a single relation could be established across a matched fleet. Finally, the experiment was repeated on both linacs at 10 MV, where the linear relationship between α and PDD 10 was again observed.Conclusions: The authors conclude that EPID image analysis of physically wedged beam profiles can be used to measure linac photon beam energy. The uncertainty in such a measurement is dominated by that associated with measuring PDD 10 in the water‐tank; hence, the accuracies of these two methods are directly comparable. This method provides a useful technique for quickly performing energy constancy measurements while saving significant clinical downtime for QA.