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CompHEP: Present and Future Alexandre Kryukov on behalf of CompHEP collaboration (E. Boos, V. Bunichev, M. Dubinin, L. Dudko, V. Ilyin, A. Kryukov, V.

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Presentation on theme: "CompHEP: Present and Future Alexandre Kryukov on behalf of CompHEP collaboration (E. Boos, V. Bunichev, M. Dubinin, L. Dudko, V. Ilyin, A. Kryukov, V."— Presentation transcript:

1 CompHEP: Present and Future Alexandre Kryukov on behalf of CompHEP collaboration (E. Boos, V. Bunichev, M. Dubinin, L. Dudko, V. Ilyin, A. Kryukov, V. Edneral V. Savrin, A. Semenov, A. Sh.)

2  General motivation and goals  How CompHEP works: symbolic and numerical parts  Physics Models  Flavour combinatorics simplification  Large-scale calculations: distributive calculation, batch scripts  Interface to PYTHIA  MCDB – MC Database for particle event samples -> L.Dudko, next report.  Concluding remarks Outline

3 The increase of the collider energies requires simulation of processes for more and more complex processes with better and better precision (NLO, NNLO, NLL resummation) 1.LEP I – basically 2 fermion physics; 2.LEP II – basically 4 fermion physics; 3.TEVATRON, LHC and LC – 4,5,6 and even 8 fermion physics with additional hard photons and/or gluons (jets); ● Single top in the t-channel mode – 5 fermions; ●Top pair production with decays – 6 fermions; ●Strongly interacting Higgs sector in hadron collisions – 6 fermions ● Yukawa coupling – 8 fermions Physical motivation

4 A number of automatic (may be partly) programs can be found on the market: CompHEP, GRACE, MadGraph, AlpGen, Omega/WHIZARD, Amegic,... Goals:  Automation of tree level diagram calculations  A full computational chain from Lagrangian until event flow.  Interfacing to other generators (for showering and hadronization) for full simulation.  Interfacing to NLO cross section calculators (programs calculating full NLO or higher “number”) Technical motivation Large number of diagrams and large number of subprocesses (Tevatron, LHC)

5 Very incomplete list of processes computed by means of CompHEP in the past: CompHEP (Computation in High Energy Physics)

6  CompHEP generates Tree Level Feynman diagrams for a given parton process  Symbolically calculates squared Feynman diagrams. User (mostly for theoretical investigation) can output precise symbolic formular for squared matrix elements.  MC algorithm to obtain total cross section, different distribution and generation of event flow.  Rich set of model: CompHEP can work with 0,1/2,1-spin particles, Majorana and Dirac spinors, ghosts fields, 3- and 4-leg vertices.  User-friendly interface: GUI interfaces for symbolic and numerical CompHEP parts, case sensitive build-in help (F1), simple batch scripts. CompHEP ideas

7  Choose physics model : SM, MSSM, your own. User can change model parameters (masses, couplings, etc.), add/remove/change vertices and composite particles in existing models or in his(her) own models.  Set initial beams or decay particle and set a final state. CompHEP generates corresponding Feynman diagrams. User can look at and remove some particular diagrams or subprocesses.  Prepare a numerical MC generator. CompHEP squares and symbolically calculates the diagrams. After that it can keep them as a C/REDUCE/FORM code. The most applicable case – C code. By standard make CompHEP compiles and links a program for numerical calculations for the process (numerical Monte-Carlo generator) How CompHEP works (symbolic).

8  Set necessary kinematic cuts, Q 2, PDF set, etc.  Customize numerical MC generator. The most complicated part is selection of right phase space parametrization and regularizations of singularities.  Calculate full cross section and distributions. CompHEP uses adaptive VEGAS algorithm for MC calculations. User may set different variables (P T, inv. mass, rapidity, etc.) to draw corresponding distributions.  Generates events. After cross section calculation CompHEP can generate events for the given process. User set a number of the events. If the process consists of some subprocesses, the procedure applies to the each subprocess. How CompHEP works (numerical).

9 There are several models implemented in CompHEP:  Simple “teaching” models: QED and Fermi Model  Standard Model both in unitary and t'Hooft-Feynman gauges  Complete MSSM both in unitary and t'Hooft-Feynman gauges with the Higgs sector.  mSUGRA and GMSB models. ● The FeynHiggs and ISASUSY library are necessary.  Some models are available by request: ● Top quark Lagrangian with anomalous couplings as follows from the dimension 6 effective operators ● Excited fermion Model ● Complete two-Higgs-doublet Model with conserved or broken CP invariance LanHEP program (the part of the CompHEP project) allows to generate Fynmann rules for new models from (effective) Lagrangian. CompHEP Models

10 A serious computational problem is the large number of partonic subprocesses at hadron machines (for example, pp-> W+jj consist of 472 subprocesses). Reasons:  Many quark partons with different flavors  Many additional diagrams for each subprocess because of CKM quark mixing Basic ideas:  Rotation of down quarks: thus, transfering the mixing matrix elements from vertices of subprocess Feynman diagrams to PDFs  Diagrams are divided into gauge invariant classes which are convoluted with different combinations of PDFs Simplification of Flavour Combinatorics * E.Boos, et al. JHEP 0005 (2000) 052

11 “Hash” models in CompHEP. Transferring of CKM elements to PDFs allows to unify two generations of light quarks to one – “hash” generation – (u#, d#) Two approximations: 1) M u = M d = M s = M c = 0 Advantage: 1.SM, pp-->W+jj: 472 processes, 6160 diagrams 2.Hash SM: 42 subprocesses, 532 diagrams Simplification of Flavour Combinatorics

12 Symbolic batch (symb_batch.pl)  All parameters are set in a file (process.dat) and scipts launches CompHEP in a non-GIU mode with these parameters Numerical batch (num_batch.pl)  MC generators parameters are kept in one file (batch.dat) for all subprocesses  The batch script starts numerical calculations including all (or some) usual steps in CompHEP – cross section calculation, event generation  MC generator customization is realized by hands or in GUI mode.  num_batch.pl has detailed help (run./num_batch.pl –help) Larga-scale calculations: batch regime

13 CompHEP have to use external generators for hadronization and parton showering: Problems:  Interfacing Squared Matrix Element generators with Showering and Hadronizating generators): Les Houches Accord 1, event file formats;  Les Houches Accord 2: uniform interface to different PDF sets.  Les Houches Accord 3: Interfacing SUSY codes to MC generators for parameters, spectrum, decays; Generator environment

14 The CompHEP-PYTHIA interface allows to use processes 2-- >2..6 computed by CompHEP as new processes for PYTHIA Main goal: provide ISR/FSR, hadronization (including jet fragmentation) and decays by PYTHIA.  CompHEP generates unweighted events and writes to event files.  Special mix_flows utility mixes several event files in one event file according to their relative contributions to cross section. The file can is used by PYTHIA as input.  We provide the interface library and an example of program (main.f). CompHEP 4.4 – PYTHIA 6.2 interface

15  CompHEP with the interface to PYTHIA is a powerful tool for a simulation of different physical processes at hadron and lepton colliders.  CompHEP allows to study problem for wide set of physics models: SM, MSSM (two gauges, some SUSY violation scenarios). Physicist can create and use own model.  Comphep calculates cross section, prepares different distributions, generates unweighted event flow and more.  CompHEP is compatible with Les Houches Accord I. The interface with Pythia allows to generate event flow that is ready for further investigations by phenomenologiests and/or experimentalists.  Symbolic and numerical batch modes simplify large-scale calculations  The CompHEP is the LO program. However it allows to include (partly) some NLO corrections: NLO Tree Level 2-->N+1 corrections to the process 2->N can be computed. One can include NLO structure functions, loop relations between parameters (K-factors), and existing from papers loop contributions as effective vertices (functions). Concluding Remarks

16 The nearest plans:  Development of distributed Monte-Carlo calculation and event generation on computer clusters as well as GRID capabilities.  Implementation of the FORM computer algebra program for symbolic calculations: form-factors, new symbolic algorithms, models with extra dimensions, dimensional regularization, spin density matrices for external lines of squared diagrams;  Les Houches Accord I based interface to HERWIG;  Les Houches Accord II based interface to PDFs;  SUSY Les Houches Accord (III) based interface to various SUSY parameter, mass (etc.) calculation codes. The long term plans:  Amplitude techniques for symbolical and numerical calculations including the 1-loop case.  Automation of regularization singularities.  Incorporation of the gauge invariant classes of diagrams. Future plans

17  CompHEP collaboration: E. Boos, V. Bunichev, M. Dubinin, L. Dudko, V. Ilyin, A. Kryukov, V. Edneral, V. Savrin, A. Semenov, A. Sh.  CompHEP homepage: http://theory.sinp.msu.ru/comphep There are CompHEP itself, LanHEP, cpyth (CompHEP-PYTHIA interface)  References:  early CompHEP versions (3.**, 41.10): A. Pukhov et al., Preprint INP MSU 98-41/542, hep-ph/9908288.  recent CompHEP versions (4.2p1, 4.4.0): E. Boos et all., CompHEP 4.4.0, hep-ph/0403123, will be published in Proceedings of ACAT’03 General information

18 CompHEP Collaboration (incomplete list)


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