Was reading up on diffraction (and hunting for some info on Northrop's work) and came across the textbook "Fundamentals of the Physical Theory of Diffraction" by Ufimtsev, which had a foreword by Kenneth Mitzner (who worked on the B-2 for Northrop), in which he said (in the quote "PTD" refers to Ufimtsev's physical theory of diffraction):
There are alternative methods for numerical approximation of RF diffraction which like PTD account for the contributions from edges/discontinuities, but have more limitations than PTD. One method was devised by Joseph Keller around the early 1950s, called the "geometrical theory of diffraction" (GTD, and it's extension the "method of equivalent currents", MEC), but I haven't found any traces of a possible link of Keller's work to Northrop during their pre-B-2 development (ie. XST project).
For the timeline in question (1950s-1970s) published numerical solutions to RF scattering (which included edge/discontinuity effects) were either PTD or GTD based, so I'm really curious as to what Northrop might have been using for their pre-B-2 XST development.
So it seems at least for the B-2, Northrop shifted to using Ufimtsev's methods to numerically approximate RF scattering.
There are alternative methods for numerical approximation of RF diffraction which like PTD account for the contributions from edges/discontinuities, but have more limitations than PTD. One method was devised by Joseph Keller around the early 1950s, called the "geometrical theory of diffraction" (GTD, and it's extension the "method of equivalent currents", MEC), but I haven't found any traces of a possible link of Keller's work to Northrop during their pre-B-2 development (ie. XST project).
For the timeline in question (1950s-1970s) published numerical solutions to RF scattering (which included edge/discontinuity effects) were either PTD or GTD based, so I'm really curious as to what Northrop might have been using for their pre-B-2 XST development.
