Interest for digital processing of signals from radia- tion detectors is subject to a growing attention due to its intrinsic adaptivity, easiness of calibration, etc. This work comparcs two digital processing methods: a multiple-delay-line (DL)N filtcr and a least-mean-squares (LMS) adaptive filter for applications in high resolution X-ray spectroscopy. The signal pulse, as appears at the output of a proper analog conditioning circuit, is digitized: the samples undergo a digital filtering procedure. Both digital filters take advantage of the possibility of synthesizing the best possible weighting function with respect to the actual noise Conditions. A noticeable improvement of more than 10% in energy resolution has been achieved with both systems with respect to state-of-the-art systems based on analog circuitry. In particular, the two digital processors are shown to be the best choice respectively: for on-line use with critical ballistic deficit conditions and for very-high-resolution spectroscopy systems, ultimately limited by l/f noise.
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