Luis J. Gomez
Duke University
50 Papers
65 Citations
Luis J. Gomez is an academic researcher from Duke University. The author has contributed to research in topics: Electromagnetic coil & Computer science. The author has an hindex of 9, co-authored 38 publications. Previous affiliations of Luis J. Gomez include Purdue University & Lawrence Berkeley National Laboratory.
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Papers
Design of transcranial magnetic stimulation coils with optimal trade-off between depth, focality, and energy.
TL;DR: The presented results appear to be the first significant advancement in the depth-focality trade-off of TMS coils since the introduction of the figure-8 coil three decades ago, and likely represent the fundamental physical limit.
Conditions for numerically accurate TMS electric field simulation
TL;DR: This work systematically quantify their numerical error and provides guidelines for their setup to ensure the accuracy of TMS E-field simulations, including the finite element method with and without superconvergent patch recovery, boundary element method (BEM), finite difference method (FDM), and coil modeling methods.
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Fast computational optimization of TMS coil placement for individualized electric field targeting.
TL;DR: A fast computational auxiliary dipole method (ADM) for determining the optimum coil position and orientation was developed in this article. But it is not yet suitable for the use of E-field measurements.
87
Numerical Analysis and Design of Single-Source Multicoil TMS for Deep and Focused Brain Stimulation
TL;DR: A systematic, genetic algorithm-based technique for synthesizing multichannel arrays that minimize the volume of the excited region required to achieve a prescribed penetration depth and maintain realistic values for the input driving currents is proposed.
56
Design of Transcranial Magnetic Stimulation Coils with Optimal Trade-off between Depth, Focality, and Energy
TL;DR: The presented results appear to be the first significant advancement in the depth–focality trade-off of TMS coils since the introduction of the figure-8 coil three decades ago, and likely represent the fundamental physical limit.
53