180 References [113] E. Chabert, C. Diaconu, S. Kermiche, I. Negri, C. Vallee, “QBGFMAR - an Updated PHAN Package for Cosmic and Halo Muon Topological Rejection in High P T Physics Analysis,” <strong>H1</strong>-Internal Note, vol. <strong>H1</strong>-11/98-556, DESY, 1998. [114] F. Jacquet and A. Blondel, “Report from the Study Group on Detectors for Charged Current Events,” *Hamburg 1979, Proceedings, Study of an ep Facility for Europe*, Hamburg 1979, 377-414. [115] J.F.Kenney and E.S.Keeping, “Mathematics of Statistics, NJ: Van Nostrand, 1962,” [116] A. Hocker et al., “TMVA: Toolkit for multivariate data analysis,” PoS, vol. ACAT, p. 040, 2007, physics/0703039. [117] P.Domingos and M. Pazzani, “On the Optimality of the Simple Bayesian Classifier under Zero-One Loss,” Machine Learning, vol. 29, pp. <strong>10</strong>3–130, 1997. [118] B. Heinemann, Measurement of Charged Current and Neutral Current Cross Sections in Positron-Proton Collisions at sqrt(s)=300 GeV. PhD thesis, University of Hamburg, 1999. [119] H. Collaboration, “Deeply Virtual Compton Scattering and its Beam Charge Asymmetry in e ± p Collisions at HERA,” 2009, 0907.5289. [120] M. Peez, B. Portheault, E. Sauvan, “An Energy Flow Algorithm for Hadronic Reconstruction in OO: Hadroo2,” <strong>H1</strong>-Internal Note, vol. <strong>H1</strong>-01/05-616, DESY, 2005. [121] V. Blobel, “An unfolding method for high energy physics experiments,” 2002, hepex/0208022. [122] R. Brun and F. Rademakers, “ROOT: An object oriented data analysis framework, TUnfold package,” [123] P. C. Hansen, “The l-curve and its use in the numerical treatment of inverse problems, http://www.imm.dtu.dk/ pch/tr/lcurve.ps,” Advances in Computational Bioengineering. [124] G. D’Agostini, “On the use of the covariance matrix to fit correlated data,” Nucl. Instrum. Meth., vol. A346, pp. 306–311, 1994. [125] F. Abe et al., “Measurement of Double Parton Scattering in ¯pp Collisions at √ s = 1.8 TeV,” Phys. Rev. Lett., vol. 79, pp. 584–589, 1997. [126] L. Marti, Multiple Parton Interactions in Photoproduction at HERA/<strong>H1</strong>. PhD thesis, University of Hamburg, 2009. [127] C. Gwenlan, “Multijets in Photoproduction at HERA,” Acta Phys. Polon., vol. B33, pp. 3123–3128, 2002. [128] S. Aid et al., “Jets and Energy Flow in Photon - Proton Collisions at HERA,” Z. Phys., vol. C70, pp. 17–30, 1996, hep-ex/951<strong>10</strong>12.
References 181 [129] J. M. Butterworth, J. R. Forshaw, and M. H. Seymour, “Multiparton Interactions in Photoproduction at HERA,” Z. Phys., vol. C72, pp. 637–646, 1996, hepph/9601371. [130] T. Sjostrand and M. van Zijl, “A Multiple Interaction Model for the Event Structure in Hadron Collisions,” Phys. Rev., vol. D36, p. 2019, 1987. [131] S. Magill, ed., Optimization of Jet Algorithm Inputs in the ZEUS Detector, Proceedings of the IX International Conference on Calorimetry in High Energy Physics, vol. XXI, (Annecy Le Vieux Cedex, France), October 2000. [132] B. T.Carli Nucl.Instrum.Meth.A501, p. 576, 2003. hep-ex/021<strong>10</strong>19. [133] R. Sedgewick, Algorithms in C++, ch. 26. Addison Wesley, 1992. [134] B. V. Dasarathy, Nearest Neighbor (NN) Norms: NN Pattern Classification Techniques. Los Alamitos, Calif. : IEEE Computer Society Press, 1991. ISBN 0-8186- 8930-7. [135] R.A.Fisher, “The use of multiple measurements in taxoconic problems,” Annals Eugenics, vol. 7, p. 179, 1936. [136] C.Bishop, Neural Networks for Pattern Recognition. Oxford: Clarendon Press, 1995. [137] E. Bishop, “A generalization of the stone-weierstrass theorem,” Pacific J. Math., vol. 11, no. 3, pp. 771–783, 1961. [138] P.Werbos, The Roots of Backpropagation. New York: Wiley, 1994. [139] C. Burges, “A tutorial on support vector machines for pattern recognition,” Data Mining and Knowledge Discovery, vol. 2, p. 1, 1998. [140] Y. Freund and R. Schapire, “A decision-theoretic generalization of on-line learning and an application to boosting.,” Journal of Computer and System Science, vol. 55, pp. 119–139, 1997.
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