The WHIZARD Event Generator: The Generator of Monte Carlo Event Generators for Tevatron, LHC, ILC, CLIC, CEPC, FCC-ee, FCC-hh, SppC and other High Energy Physics Experiments. WHIZARD is a program system designed for the efficient calculation of multi-particle scattering cross sections and simulated event samples. Tree-level matrix elements are generated automatically for arbitrary partonic processes by using the Optimized Matrix Element Generator O’Mega. Matrix elements obtained by alternative methods (e.g., including loop corrections) may be interfaced as well. The program is able to calculate numerically stable signal and background cross sections and generate unweighted event samples with reasonable efficiency for processes with up to eight final-state particles; more particles are possible. For more particles, there is the option to generate processes as decay cascades including complete spin correlations. Different options for QCD parton showers are available. Polarization is treated exactly for both the initial and final states. Final-state quark or lepton flavors can be summed over automatically where needed. For hadron collider physics, an interface to the standard LHAPDF is provided. For Linear Collider physics, beamstrahlung (CIRCE) and ISR spectra are included for electrons and photons. The events can be written to file in standard formats, including ASCII, StdHEP, the Les Houches event format (LHEF), HepMC, or LCIO. These event files can then be hadronized. WHIZARD supports the Standard Model and a huge number of BSM models. Model extensions or completely different models can be added. There are also interfaces to FeynRules and SARAH.

References in zbMATH (referenced in 17 articles )

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  1. A. Dedes, M. Paraskevas, J. Rosiek, K. Suxho, L. Trifyllis: SmeftFR - Feynman rules generator for the Standard Model Effective Field Theory (2019) arXiv
  2. Bury, M.; van Hameren, A.: Numerical evaluation of multi-gluon amplitudes for high energy factorization (2015)
  3. Staub, Florian: Exploring new models in all detail with \textttSARAH (2015)
  4. Alwall, J.; Frederix, R.; Frixione, S.; Hirschi, V.; Maltoni, F.; Mattelaer, O.; Shao, H.-S.; Stelzer, T.; Torrielli, P.; Zaro, M.: The automated computation of tree-level and next-to-leading order differential cross sections, and their matching to parton shower simulations (2014)
  5. Staub, Florian: SARAH 4: a tool for (not only SUSY) model builders (2014)
  6. Belyaev, Alexander; Christensen, Neil D.; Pukhov, Alexander: CalcHEP 3.4 for collider physics within and beyond the standard model (2013)
  7. Ita, Harald; Ozeren, Kemal: Colour decompositions of multi-quark one-loop QCD amplitudes (2012)
  8. Alwall, Johan; Herquet, Michel; Maltoni, Fabio; Mattelaer, Olivier; Stelzer, Tim: MadGraph 5: going beyond (2011)
  9. Chung, C. H.; Krämer, Michael; Robens, T.: An alternative subtraction scheme for next-to-leading order QCD calculations (2011)
  10. Dixon, Lance J.; Henn, Johannes M.; Plefka, Jan; Schuster, Theodor: All tree-level amplitudes in massless QCD (2011)
  11. Duhr, Claude; Fuks, Benjamin: A superspace module for the FeynRules package (2011)
  12. Becker, Sebastian; Reuschle, Christian; Weinzierl, Stefan: Numerical NLO QCD calculations (2010)
  13. Binoth, T.; Boudjema, F.; Dissertori, G.; Lazopoulos, A.; Denner, A.; Dittmaier, S.; Frederix, R.; Greiner, N.; Höche, S.; Giele, W.; Skands, P.; Winter, J.; Gleisberg, T.; Archibald, J.; Heinrich, G.; Krauss, F.; Maître, D.; Huber, M.; Huston, J.; Kauer, N.; Maltoni, F.; Oleari, C.; Passarino, G.; Pittau, R.; Pozzorini, S.; Reiter, T.; Schumann, S.; Zanderighi, G.: A proposal for a standard interface between Monte Carlo tools and one-loop programs (2010)
  14. Edelhäuser, Lisa; Porod, Werner; Singh, Ritesh K.: Spin discrimination in three-body decays (2010)
  15. Frederix, R.; Gehrmann, T.; Greiner, N.: Integrated dipoles with MadDipole in the MadGraph framework (2010)
  16. Gehrmann, T.; Greiner, N.: Photon radiation with MadDipole (2010)
  17. Mastrolia, P.; Ossola, G.; Reiter, T.; Tramontano, F.: Scattering amplitudes from unitarity-based reduction algorithm at the integrand-level (2010)