Robust Computation in 2D Absolute EIT (a-EIT) Using D-bar Methods with the `exp' Approximation
For medical EIT imaging, this work shows that absolute imaging, previously considered infeasible due to sensitivity to errors, may be achievable with D-bar methods.
This paper demonstrates that D-bar reconstruction methods for absolute Electrical Impedance Tomography (EIT) are robust to modeling errors and noise, producing absolute images with artefacts similar to time-difference EIT. Experimental tank data from multiple EIT systems confirm the robustness.
Objective: Absolute images have important applications in medical Electrical Impedance Tomography (EIT) imaging, but the traditional minimization and statistical based computations are very sensitive to modeling errors and noise. In this paper, it is demonstrated that D-bar reconstruction methods for absolute EIT are robust to such errors. Approach: The effects of errors in domain shape and electrode placement on absolute images computed with 2D D-bar reconstruction algorithms are studied on experimental data. Main Results: It is demonstrated with tank data from several EIT systems that these methods are quite robust to such modeling errors, and furthermore the artefacts arising from such modeling errors are similar to those occurring in classic time-difference EIT imaging. Significance: This study is promising for clinical applications where absolute EIT images are desirable, but previously thought impossible.