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Deep Learning Analysis of Deeply Virtual Exclusive Photoproduction

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arxiv 2012.04801 v1 pith:TJQQJTVW submitted 2020-12-09 hep-ph nucl-exphysics.comp-phphysics.data-an

Deep Learning Analysis of Deeply Virtual Exclusive Photoproduction

classification hep-ph nucl-exphysics.comp-phphysics.data-an
keywords deeplylearningunpolarizedvirtualapproachcrossdatadeep
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We present a Machine Learning based approach to the cross section and asymmetries for deeply virtual Compton scattering from an unpolarized proton target using both an unpolarized and polarized electron beam. Machine learning methods are needed to study and eventually interpret the outcome of deeply virtual exclusive experiments since these reactions are characterized by a complex final state with a larger number of kinematic variables and observables, exponentially increasing the difficulty of quantitative analyses. Our deep neural network (FemtoNet) uncovers emergent features in the data and learns an accurate approximation of the cross section that outperforms standard baselines. FemtoNet reveals that the predictions in the unpolarized case systematically show a smaller relative median error than the polarized that can be ascribed to the presence of the Bethe Heitler process. It also suggests that the $t$ dependence can be more easily extrapolated than for the other variables, namely the skewness, $\xi$ and four-momentum transfer, $Q^2$. Our approach is fully scalable and will be capable of handling larger data sets as they are released from future experiments.

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    A neural network framework informed by lattice QCD uses all-order dispersion relations to significantly constrain both real and imaginary parts of Compton Form Factors extracted from DVCS proton data.