The hard pulse approximation for the AKNS (2 × 2)-system

Charles L. Epstein, Jeremy F. Magland

Type: Article

Publication Date: 2009-09-16

Citations: 1

DOI: https://doi.org/10.1088/0266-5611/25/10/105006

Abstract

In the hard pulse approximation, commonly used in nuclear magnetic resonance, one considers potentials for the AKNS system that are sums of δ-functions. The system of differential equations does not, strictly speaking, make sense for such potentials. In Magland (2004 PhD Thesis (arXiv:0903.4363)) an analogous discrete forward and inverse problem is analyzed. We review these results and show that pulses obtained using the inverse scattering transform for this hard pulse approximation converge to the expected continuum potential both uniformly and in the L1-norm. We also show that the AKNS system makes sense with potentials that are non-atomic measures with finite total variation.

Locations

Inverse Problems - View
CiteSeer X (The Pennsylvania State University) - View - PDF

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+	ON A PALEY-WIENER THEOREM FOR THE ZS-AKNS SCATTERING TRANSFORM	2013	Ryan Walker

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+	Scattering and inverse scattering for first order systems	1984	Richard Beals Ronald R. Coifman
+	Numerical realization of the inverse scattering method	1990	I. T. Habibullin A. G. Shagalov
+	A numerical solution to the Zakharov-Shabat inverse scattering problem	1991	Panayiotis Frangos D.L. Jaggard
+ PDF Chat	Introduction to magnetic resonance imaging for mathematicians	2004	Charles L. Epstein
+	Discrete Inverse Scattering Theory for NMR Pulse Design	2009	Jeremy F. Magland