TY - JOUR
T1 - Resonance parameter adjustment based on integral experiments
AU - Sobes, Vladimir
AU - Leal, Luiz
AU - Arbanas, Goran
AU - Forget, Benoit
PY - 2016/7
Y1 - 2016/7
N2 - This project seeks to allow coupling of differential and integral data evaluation in a continuousenergy framework and to use the generalized linear least-squares (GLLS) methodology in the TSURFER module of the SCALE code package to update the parameters of a resolved resonance region evaluation. Recognizing that the GLLS methodology in TSURFER is identical to the mathematical description of a Bayesian update in SAMMY, the SAMINT code was created to use the mathematical machinery of SAMMY to update resolved resonance parameters based on integral data. Traditionally, SAMMY used differential experimental data to adjust nuclear data parameters. Integral experimental data, such as in the International Criticality Safety Benchmark Experiments Project, remain a tool for validation of completed nuclear data evaluations. SAMINT extracts information from integral benchmarks to aid the nuclear data evaluation process. Later, integral data can be used to resolve any remaining ambiguity between differential data sets, highlight troublesome energy regions, determine key nuclear data parameters for integral benchmark calculations, and improve the nuclear data covariance matrix evaluation. SAMINT is not intended to bias nuclear data toward specific integral experiments but should be used to supplement the evaluation of differential experimental data. Using GLLS ensures proper weight is given to the differential data.
AB - This project seeks to allow coupling of differential and integral data evaluation in a continuousenergy framework and to use the generalized linear least-squares (GLLS) methodology in the TSURFER module of the SCALE code package to update the parameters of a resolved resonance region evaluation. Recognizing that the GLLS methodology in TSURFER is identical to the mathematical description of a Bayesian update in SAMMY, the SAMINT code was created to use the mathematical machinery of SAMMY to update resolved resonance parameters based on integral data. Traditionally, SAMMY used differential experimental data to adjust nuclear data parameters. Integral experimental data, such as in the International Criticality Safety Benchmark Experiments Project, remain a tool for validation of completed nuclear data evaluations. SAMINT extracts information from integral benchmarks to aid the nuclear data evaluation process. Later, integral data can be used to resolve any remaining ambiguity between differential data sets, highlight troublesome energy regions, determine key nuclear data parameters for integral benchmark calculations, and improve the nuclear data covariance matrix evaluation. SAMINT is not intended to bias nuclear data toward specific integral experiments but should be used to supplement the evaluation of differential experimental data. Using GLLS ensures proper weight is given to the differential data.
KW - Continuous-energy coupled
KW - Differential and integral experimental data
KW - Nuclear data evaluation
UR - http://www.scopus.com/inward/record.url?scp=84983314171&partnerID=8YFLogxK
U2 - 10.13182/NSE15-50
DO - 10.13182/NSE15-50
M3 - Article
AN - SCOPUS:84983314171
SN - 0029-5639
VL - 183
SP - 347
EP - 355
JO - Nuclear Science and Engineering
JF - Nuclear Science and Engineering
IS - 3
ER -