TY - GEN
T1 - Connecting physics models and diagnostic data using bayesian graphical models
AU - Svensson, J.
AU - Ford, O.
AU - Werner, A.
AU - Von Nessi, G.
AU - Hole, M.
AU - McDonald, D. C.
AU - Appel, L.
AU - Beurskens, M.
AU - Boboc, A.
AU - Brix, M.
AU - Howard, J.
AU - Blackwell, B. D.
AU - Bertram, J.
AU - Pretty, D.
PY - 2010
Y1 - 2010
N2 - With increasingly detailed physics questions to ask, and with more advanced diagnostics available, there is a strong case for trying to generalise the way analysis of diagnostic data, and connection to underlying physics models, is done in today's experiments. With current analysis chains, it is difficult, verging on impossible, to fully grasp the exact assumptions, hidden in different legacy codes, that goes into a full analysis of the main physics parameters in an experiment. We show that by using Bayesian probability theory as the underlying inference method, it is possible to generalise scientific analysis itself, and therefore build an effective and modular scientific inference software infrastructure. The Minerva framework [1,2] uses the concept of Bayesian graphical models [3] to model the full set of dependencies, functional and probabilistic, between physics assumptions and diagnostic raw data. Using a graph structure, large scale inference systems can be modularly built that optimally and automatically use data from multiple sensors. The framework, used at the JET, MAST, H1 and W7-X experiments, is exemplified by a number of JET applications, ranging from inference on the flux surface topology to profile inversions from multiple diagnostic systems.
AB - With increasingly detailed physics questions to ask, and with more advanced diagnostics available, there is a strong case for trying to generalise the way analysis of diagnostic data, and connection to underlying physics models, is done in today's experiments. With current analysis chains, it is difficult, verging on impossible, to fully grasp the exact assumptions, hidden in different legacy codes, that goes into a full analysis of the main physics parameters in an experiment. We show that by using Bayesian probability theory as the underlying inference method, it is possible to generalise scientific analysis itself, and therefore build an effective and modular scientific inference software infrastructure. The Minerva framework [1,2] uses the concept of Bayesian graphical models [3] to model the full set of dependencies, functional and probabilistic, between physics assumptions and diagnostic raw data. Using a graph structure, large scale inference systems can be modularly built that optimally and automatically use data from multiple sensors. The framework, used at the JET, MAST, H1 and W7-X experiments, is exemplified by a number of JET applications, ranging from inference on the flux surface topology to profile inversions from multiple diagnostic systems.
UR - http://www.scopus.com/inward/record.url?scp=84875675733&partnerID=8YFLogxK
M3 - Conference contribution
SN - 9781622763313
T3 - 37th EPS Conference on Plasma Physics 2010, EPS 2010
SP - 169
EP - 172
BT - 37th EPS Conference on Plasma Physics 2010, EPS 2010
T2 - 37th EPS Conference on Plasma Physics 2010, EPS 2010
Y2 - 21 June 2010 through 25 June 2010
ER -