Interactive graphical computing for simulating and unfolding measured distributions.

TL;DR: In this paper, a method for measuring fluxes and energy spectra of high energy hadron cascade particles in the energy range of tens to hundreds of MeV was described, and a multitude of spallation reactions induced in copper foils were identified and quantitatively measured by the use of high resolution Ge(Li) gamma spectroscopy and computerized analysis.

TL;DR: In particular, the energy dependent radiation spectrum or integral quantities, such as the total flux, dose rate or reaction rates, are of interest in these measurements as discussed by the authors, and activation detectors are widely used in measurements of radiation fields.

TL;DR: The LOUHI82 program as discussed by the authors is a general purpose least square unfolding program, which is based on the minimization of the weighted square sum of the fitting errors of activities and several alternative terms related to the smoothness and assumed shape of the solution, allowing varying degrees of a priori information.

TL;DR: The health physicist working around high-energy accelerators has the advantage over identical professionals working in more conventional centers of being associated with the most advanced techniques in many scientific fields, particularly those connected with particle detection.

TL;DR: The purpose of the present note is to show how the same result can be obtained in a way which requires the inversion of only one matrix, whereas the method described by Phillips involves the inversions of two matrices.

TL;DR: In this article, a mathematical formalism for the representation of photopeaks and the continua in their vicinity is presented for computer analysis of γ-ray spectra from semiconductor detector systems.

TL;DR: A method for the numerical solution of a Fredholm integral equation of the first kind is derived and illustrated and the trace of the covariance matrix of the error in the solution is used to estimate the accuracy of the results.

TL;DR: In this article, the FERDoR unfolding method and code are used to transform the measured pulse-height distribution into a neutron spectrum, which produces an estimate of the neutron spectrum with a rigorous confidence interval.