\TN{05--6--1048--2003/2010}{1}{\tscom}
{Information, Computer and Network Support of JINR's Activity}
{V.V.~Ivanov\\V.V.~Korenkov\\P.V.~Zrelov}
\TA Provision of theoretical and experimental research conducted by the JINR
Member State institutes at JINR and other scientific centers with modern
telecommunication, network and information resources. In order to fulfill
the task, it is necessary: to provide JINR and its Member States with high-speed
telecommunication data links; to provide fault-tolerant operation and further
development of the high-speed and protected local area network of JINR;
to provide development and maintenance of the distributed high-performance
computing infrastructure and mass storage resources; to provide information,
algorithmic and software support of the research-and-production activity of
the Institute; to provide a reliable operation and development of the JINR Grid-segment
as a component of the global Grid-structure.
%%\vspace*{4mm}
{\bf Expected main results in 2010:}
\begin {itemize}
%1
\item Development of the JINR external telecommunication links: lunching and maintenance
of the reliable functioning of the 10 Gbps high-speed JINR-Moscow data link on the basis
of SCC ``Dubna''. Optimization of access to the Russian and global networks (RBNET,
RUNNET, RUHEP, RASNET, GEANT3). Con\-struc\-tion of a system of IP-telephony in
JINR. Securing reliable operation of JINR connections with Tier1 centers:
CERN - for CMS experiment, FZK (Karlsruhe) - for ALICE experiment and SARA (Amsterdam) -
for ATLAS experiment. Start-up of the project on the development of the corporate
network of JINR and its Member States.
%2
\item Provision of secured, reliable and failure-tolerant work of the JINR backbone main
communication facility; modernization of the power supply of the central LAN facility.
Provision of the reliable and effective operation of the Institute's gigabit network
highway. Stage-by-stage transition of the JINR Backbone to a data transfer rate
of 10 Gbps.
%3
\item Development and maintenance of a reliable functioning of the JINR Central Information
Computing Complex (CICC). Rise of the CICC performance and disk space increase for data
storage needed by ATLAS, ALICE, CMS experiments and other projects of the Institute.
Provision of support of general purpose software, monitoring operation nodes,
information support, user registration, and consulting service of the JINR CICC.
Development of the distributed and parallel computing paradigms. Provision of efficient
data flow control for processing, storage and effective search within mass memory
systems. Realization in JINR CICC of the prototype of a dynamic center for data
processing using the principles of "visualization" and service - oriented architecture.
%4
\item Further development of the hardware and software environment for information,
algorithmic and software support of the research activities under way at JINR
and JINR Member State institutes on the CICC basis. Technical support of the JINR
website. Modernization and support of other information servers of JINR and LIT.
Development of retrieval systems at JINR sites. Creation of a website of the editions
of ``Physics of Elementary Particles and Atomic Nuclei'' and ``Particles and Nuclei,
Letters'' journals.
Creation and support of information systems and databases in cooperation with
other JINR subdivisions, including administrative structures. Development of the system
of libraries of electronic documents related to the JINR scientific and administrative
activity. Development of the system of electronic libraries of scientific periodical
publications with access to full-text electronic versions of journals on JINR
research field. Development, creation and support of informational websites of various
workshops and conferences as well as support of sites of JINR subdivisions and
sites of conferences in a hosting mode (by request).
Further development of the JINRLIB library: update of the library with new programs
created at JINR; development of new programming systems, first of all, freely
distributed ones; improvement of the quality of statistics of the Library's programs
use; development of dynamic WEB-applications.
Support of the international program libraries CPCLIB, CERNLIB. Support of the
specialized WWW-server, provision of electronic access to programs and documentation.
Information and technical support of the users.
Creation and development of parallel analogues for traditional programs of numerical
methods, where the MPI package is supposed to be the basic tool of paralleling, and
the multicore processors are the basic computing platform.
Research on the efficiency of solving computing tasks on the JINR CICC clusters.
Consecutive development and modification of re-engineering technology of distributed
computations: further modification of the F2F converter;
adding means of automating routine works while translating Fortran programs under
package MPI control. Application of re-engineering technology to the solution of a
number of large computing tasks.
Implementation and development of paperless electronic document circulation information
system at LIT.
Development of training courses and practical classes on advanced information
technologies.
%5
\item Development of the JINR Grid segment as part of the global Grid infrastructure with a
full-function set of services: a) raising of infrastructure WLCG at JINR,
b) support of basic services of the RDIG infrastructure, c) development of the system of
monitoring and accounting the resources of the Russian LCG/EGEE segment;
d) support of Web-portals for the projects WLCG and EGEE in Russia.
De\-ve\-lop\-ment and support of the middleware and applied software of the Grid-systems:
a) certification and testing of new Grid-components, b) improvement of instrumental means
for monitoring the task performance within the Grid-environment (Dashboard, CMS
Production, FTS, Condor-G, MCDB). Creation of a Grid-infrastructure within the joint
Grid-projects with South Africa, Romania, Czech Republic and Ukraine. Participation in
the projects SKIF-Grid and GridNNN (Construction of a Grid-system of the national
nanotechnological network).
Development of a research Grid-structure for testing new components of the middleware
of Grid-structures, development of methods of "gridification" of applied software and
for work in the field of interoperability of various Grid-systems.
Support and expansion of opportunities of the HEPWEB system by introducing new generator
programs, development of special opportunities for specific experiments on LHC
(by request). Development of the training system on Grid-technologies on the basis of
the Grid-laboratory and further development of its technical basis.
Continuation of work within the project "Dubna-Grid". Expansion of the JINR segment
in frames of the system of metacluster computations "Dubna-Grid".
\end {itemize}
\begin{stage-t}
% 1
\item \PS{Providing JINR and\\ its Member States with high-speed
telecommunication\\ data links}{Korenkov V.V.\\Dolbilov A.G.}{\null}\\
\PL{LIT}{}{Korenkov V.V. + 10 per.}
%2
\item \PS{Development of the high-speed,\\ fault-tolerant, and protected\\
JINR local area network}{Ivanov V.V.\\ Popov L.A.}{\null}\\
\PL{LIT}{}{Ivanov V.V. + 6 per.\\Popov L.A. + 12 per. \\Emelin I.A. + 5 per.}\\
\PL{DLNP}{Dolbilov A.G.}{Churin I.N.\\Kovalenko R.V.}\\
\PL{LRB}{Krylov V.A. }{}\\
\PL{BLTP}{Sazonov A.A.}{}\\
\PL{FLNP}{Prikhodko V.I.}{Sukhomlinov G.A.}\\
\PL{VBLHEP}{Potrebenikov Yu.K.}{Shchinov B.G.}\\
\PL{FLNR}{Skobelev N.N.}{Polyakov A.G.}\\
\PL{UC}{Pakuliak S.Z.}{Semeniushkin I.N.}\\
\PL{SCAR}{Samoilov V.N.}{}
%3
\item \PS{Development of the distributed \\high-performance
computing\\ infrastructure and\\ mass storage resources}{Ivanov V.V.\\Korenkov V.V.\\
Mitsyn V.V.}{\null}\\
\PL{LIT}{}{Ivanov V.V. + 4 per.\\ Mitsyn V.V.+ 7 per.\\Astakhov N.S. + 8 per.}
%4
\item \PS{Development of programming \\environment for information,
algorithmic, and\\ software support of the JINR\\ research-and-production
activity}{Zrelov P.V.\\ Korenkov V.V.}{\null}\\
\PL{LIT}{}{Zrelov P.V. + 5 per.\\Korenkov V.V.+ 3 per.\\Gerdt V.P. + 1 per.\\
Kalmykova L.A.+ 8 per.\\Musulmanbekov G.G.\\Nikonov E.G.\\ Raportirenko A.M.\\
Sapozhnikov A.P.\\ Sapozhnikova T.F.+ 4 per.\\Strizh T.A. + 1 per.\\Shirikov V.P.}\\
\PL{SOIC}{Russakovich N.A.}{Borisovsky V.F.}\\
\PL{UC}{Fursaev D.V.}{Pakuliak S.Z.}
%5
\item \PS{Development of the JINR \\Grid-segment
as a component of the \\global Grid infrastructure}{Ivanov V.V.\\Korenkov V.V.\\Strizh T.A.}{\null}\\
\PL{LIT}{}{Ivanov V.V. + 12 per.\\Korenkov V.V. + 16 per.}
\end{stage-t}
\begin{intcoop}
\mtab{Armenia}{Yerevan}{YerPhI}
\mtab{}{}{IIAP NASA}
\mtab{}{}{YSU}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{}{}{JIPNR-Sosny NASB}
\mtab{}{}{BNTU}
\mtab{Bulgaria}{Sofia}{INRNE BAS}
\mtab{}{}{SU}
\mtab{CERN}{Geneva}{}
\mtab{Czech Republic}{Prague}{IP ASCR}
\mtab{Germany}{Hamburg}{DESY}
\mtab{}{Heidelberg}{Univ.}
\mtab{}{Karlsruhe}{FZK}
\mtab{}{Zeuthen}{DESY}
\mtab{Moldova}{Kishinev}{ASM}
\mtab{}{}{IAP ASM}
\mtab{Poland}{Cracow}{CYFRONET}
\mtab{}{Poznan}{IP AMU}
\mtab{}{Wroclaw}{WUT}
\mtab{Romania}{Bucharest}{IFIN-HH}
\mtab{Russia}{Moscow}{CC RAS}
\mtab{}{}{Comstar-UTS}
\mtab{}{}{IMM RAS}
\mtab{}{}{IOC RAS}
\mtab{}{}{IPI RAN}
\mtab{}{}{ISP RAS}
\mtab{}{}{ITEP}
\mtab{}{}{JSCC RAS}
\mtab{}{}{KIAM RAS}
\mtab{}{}{MPEI}
\mtab{}{}{MSU}
\mtab{}{}{RCC MSU}
\mtab{}{}{RIPN}
\mtab{}{}{RRC KI}
\mtab{}{}{RSCC}
\mtab{}{}{SINP MSU}
\mtab{}{Cherkessk}{KCSTA}
\mtab{}{Chernogolovka}{SCC IPCP RAS}
\mtab{}{Dubna}{Adm. of Dubna}
\mtab{}{}{BSINP MSU}
\mtab{}{}{``Dubna'' Univ.}
\mtab{}{}{Raduga}
\mtab{}{}{SCC ``Dubna''}
\mtab{}{Gatchina}{PNPI RAS}
\mtab{}{Nizhniy Arkhyz}{SAO RAS}
\mtab{}{Novosibirsk}{BINP SB RAS}
\mtab{}{Pereslavl-Zalesskiy}{PSI RAS}
\mtab{}{Protvino}{IHEP}
\mtab{}{Puschino}{IMPB RAS}
\mtab{}{St. Petersburg}{FIP}
\mtab{}{Troitsk}{INR RAS}
\mtab{Slovak Republic}{Kosice}{IEP SAS}
\mtab{}{}{PJSU}
\mtab{South Africa}{Cape Town}{UCT}
\mtab{Sweden}{Lund}{LU}
\mtab{Ukraine}{Kharkov}{IERT NASU}
\mtab{}{}{KFTI NASU}
\mtab{USA}{Chicago, IL}{UChicago}
\mtab{}{Pasadena, CA}{CALTECH}
\mtab{Uzbekistan}{Tashkent}{IAP NUU}
\mtab{}{}{IM UAS}
\end{intcoop}
\TN{05--6--1060--2005/2010}{1}{\tscom}
{Mathematical Support of Experimental and Theoretical Studies Conducted by JINR}
{V.V.~Ivanov\\Gh.~Adam\\P.V.~Zrelov}
\TA Performance of top research in computational mathematics and computational physics,
aimed at solving specific problems arising in experimental and theoretical research
carried out with the participation of JINR.
Mathema\-ti\-cal description and algorithmic reformulation of the physical
models such as to meet the requirement of computing solution in polynomial
time.
Development of methods and algorithms, able to extract physicall insightful information
from experimental data.
Simulation of physical processes within experimental insta\-lla\-ti\-ons.
Algo\-rithm implementation into efficient and reliable hardware adapted
programs.
The successful realization of such interdis\-cip\-li\-nary research efforts
assumes:
development of mathematical methods and tools for modeling physical
processes and experimental data analysis;
creation of methods and numerical algorithms for modeling magnetic systems;
development of software and computer complexes for experimental data processing;
ela\-bo\-ration of numerical algorithms and software for simulation of complex
physical systems;
development of methods, algorithms and software of computer algebra;
development of computing tools of a new generation. Application of the developed methods
and algorithms to other topics in science and technology (nanotechnologies, biology,
medicine, economy, industry, etc.).
%%\vspace*{4mm}
{\bf Expected main results in 2010:}
\begin {itemize}
%1
\item Modeling electronuclear installations controlled by electron beams. Modeling
photonuclear reactions of 30 MeV - 1 GeV electron beams with various targets.
Mathematical simulation of nuclear physical processes accompanying interactions of
relativistic nucleons and nuclei with matter. Simulation of neutron generation
inside large targets under irradiation with highly energetic particles and nuclei.
Study of the proton fraction of the secondary particle flux in electronuclear targets
and blankets. Analysis of the possibility of using easy material thin targets in an
accumulating ring for $\sim$100 MeV protons or deuterons. Simulation of polarization
processes in the experiment STAR at RHIC. Nuclear structure modeling and visualization
within discrete symmetry models. Numerical investigation of the scattering mechanism
in the reaction $^{8}$He+p and of the structure of the exotic nucleus $^{8}$He and
generalization of the microscopic model to the case of kaon-nuclear scattering.
Generalization of the methods and software devoted to small-angle neutron scattering
experimental data processing to encompass nanostructures and synchrotron scattering
data on multi-component phosphor-lipid membranes.
Generalization of the nonlinear thermal spike model to the description of
thermo-elastic waves and power losses of the heavy ions inside the electronic
and ionic subsystems. Study of the mutual influence of the moisture
and heat transfer processes in porous materials within a comprehensive nonlinear model.
Calculation of nuclear reaction cross-sections in the area of ultralow energies under
consideration of electronic device screening. Mathematical simulation of hadron phase
transitions achievable at the JINR accelerating installations. Computation of
radiative corrections to the $K_{e4}$-decay probability rate (for the NA48/2
experiment). Calculation of total inelastic cross-sections of the interaction of
$\pi K$-atoms with atoms of the target (for experiment DIRAC). Computation of
quarkonia pair ($J/\psi$ and $ \chi$) cross-section definition in proton - proton
and nucleus - nucleus collisions (for experiments ATLAS and ALICE). Modeling and
calculation of nuclear effects in the creation of large transverse pulse hadrons
in nucleon-nucleon, nucleon-nucleus and nucleus-nucleus collisions at RHIC and
LHC energies.
%2
\item Computer simulation and optimization of superconducting magnets for the accelerator
SIS100 designed within the FAIR project. Use of existing and newly developed software
for modeling magnetic systems for experiments conducted by JINR. Computer simulation
of the dipole magnet and the absorber for the CBM experiment. Development of methods
for modeling the operating modes of the multi-purpose isochronous cyclotron.
Development of finite element numerical methods with high order harmonic basis
functions for solving elliptic boundary-value problems and their application to
magnetostatics.
%3
\item Futher development of the TDAQ WEB Monitoring Interface for remote access to the
Control Room ATLAS at CERN and implementation in LIT the remote monitoring of data
received during sessions of ATLAS experiment. Development of neural network algorithms
and software and their tuning to the conditions of data analysis at ATLAS.
Development of methods and algorithms for event reconstruction in the CBM experiment:
particle identification by RICH, TRD, MUCH, RPC detectors; track recognition in STS,
TRD, MUCH, and global tracking for the complete system of detectors, including RICH.
Inves\-ti\-gations in the design optimization of various CBM components (RICH, TRD,
MUCH, etc.). Development of a software complex for event visualization in CBM,
participation in the activities on the development of the CBM framework software
complex. Participation in the development and implementation of ma\-the\-ma\-ti\-cal
support of the projects NICA-MPD and CBM on search and study of mixed phase in high
energy heavy ion collisions. Development of new wavelet algorithms for resonance
parameter reconstruction in the invariant mass spectrum of nucleus-nucleus interactions
and the search for hadron jets in high multiplicity events, including events with
polarized protons (experiment STAR). Development of algorithms of search for
neutrino-target vertex using information from the target tracker (experiment OPERA).
Improvement of the hard muon event reconstruction code for the CMS experiment: search
for new di-muon resonances and test of Standard Model predictions on the Drell-Yan
processes in the TeV mass region. Analysis of diffractive photo-production of vector
mesons and calculation of structure functions from data obtained in the Forward Proton
Spectrometer of the H1 detector at the HERA collider.
%4
\item Numerical analysis of the evolution of time-periodic particle-like excitations in a
model describing the signal transmission inside optical fibers by a nonlinear
parametrically driven Schroedinger equation with dissipation. Study of the
conditioning classes in the Bayesian adaptive quadrature. Development of effective
methods, algorithms and codes using adaptive local polynomial approximation
and smoothing. Further work on effective methods and algorithms of data
processing based on coordinate-parametrical polynomial model and 4-point transforms.
Study of the two-photon decays of the scalar mesons in a linear sigma-model at finite
temperature. Numerical and analytical investigation of the bifurcation points in
models of fast-rotating gravitating systems. Determination of the dipole momenta of
delta-resonances in radiative pion-nucleon scattering reactions within a
field-theoretic approach with meson-nucleon and quark-gluon degrees of freedom.
Dynamics derivation based on characteristic polynomials of n-th degree and
applications. Development of variation-iterative schemes for the numerical solution of
atom and molecule ionization models, and of ion channeling in crystals.
Quantum-mechanical modeling of the propagation of the electromagnetic impulses in
multi-component media; development of ``reaction-drift-diffusion'' type models for
multi-component media. Study of the evolution of the fundamental and the excited
states of the polaron, within the selflocalizing model of electrons in ionic crystals,
in terms of the characteristics of the medium. Modeling the critical modes in
double-layer heterogeneous Josephson junctions. Numerical study of the dynamics of
the complex systems of nonlinear equations describing the ultra-cold atom behaviour
in lattices generated from the double-well potentials. Development of a model
and a code for computing track formation in the high-temperature superconductor
$Bi_2Sr_2CaCu_2O_x $. Mathematical modeling of electromagnetic properties of metallic
nanostructures entering as basic working elements in receivers and emitters of
electromagnetic waves in SHF and UHF ranges; derivation of models describing
the electromagnetic radiation of complex structures containing nanoparticles,
such as coupled systems of nanoparticles and quantum dots, or microstrips
containing discontinuous film; mathematical modeling of the propagation of
the electromagnetic impulses in composite environments with nanoparticles
(such as a layer nanoparticles-dielectric-semiconductor).
Research of string Bianchi I and VI cosmological models in the presence of
a magnetic fluid. Development of analytical and numerical methods of computing
probabilities of pair creation of charged particles at predefined
parameters of the external field. De\-ve\-lop\-ment of analytical and numerical
methods for the reconstruction of the potential in models of nano-dimensional quantum
structures and waveguides under the consideration of the charge carrier effective
mass dependence on the space variable.
Numerical investigation of dynamical complex systems describing nonequilibrium processes in nanomaterials.(Yukalova)
%5
\item Modelling of dynamics of carbon and hydrocarbon nanostructures by considering them as discrete systems on symmetric lattices. Study of the gauge invariance in such systems and its connection with quantization. Investigation of quantum models on regular graphs, in particular, on lattices of (hydro)carbon nanostructures by methods of computer algebra and computational group theory. Development of numerical and analytical algorithms for research on the dynamics of quantum models of semiconducting nanostructures with oscillator and Coulomb potentials in external fields. The C++ implementation of involutive algorithms for constructing Boolean Groebner bases in view of allocation to the problems of Boolean satisfiability and to quantum computating. Application of technologies OpenCL and CUDA to speed-up parallel computations of algebraic Groebner and involute bases by means of graphic processors. Implementation in Aldor/Axiom of symbolic algorithms for Clifford algebras as generalization of Dirac's algebra of gamma-matrices. Study of dynamics of the mixed states of qubits and qutrits in a strong laser field. Creation of computer programs in the language Maple for computing two-loop Feynman diagrams of a propagator type with random weights of particles and for numerical and analytical computation of one-loop scalar integrals with massless particles and 2, 3, 4 and 5-dots on the internal line.
%6
\item Development of the program QuantumCircuit for modelling quantum computations in the language Mathematica by embedding quantum algorithms into it and inclusion of this program in the international database containing the quantum computing simulators. Development of algorithmic methods for quantitative analysis of the entanglement for the mixed two-qubit states, as one of the basic resources in quantum computing.
Numerical modeling of nonlinear evolution of biophysical systems and investigation of their stable states.(Yukalova)
Development of analytical and
numerical methods, of adaptive and parallel algorithms for solving nonlinear equations
and systems of nonlinear evolution equations arising in the study of overcritical
systems, of three-dimensional macromolecular structures, and in the computation of
the interaction of protein molecules with liquids. Study of the functionally
important genome elements from the distributions of their electrostatic potentials.
Molecular cartography of DNA, RNA and proteins using a distributed computing environment.
Numerical modeling of the nonlinear evolution of the biophysical systems.
Development of new approaches to local network protection, control and modeling of
the network traffic. Stable separation of various components of the time series of
interest. New formulations and solutions of computing process optimization problems
in Grid-systems under highly intensive user service requirements and various
distribution time laws of application receipt.
\end {itemize}
\begin{stage-t}
%1
\item \PS{Mathematical methods and tools for modeling physical
processes and experimental data analysis}{Ivanov V.V.\\Zrelov P.V.}{\null}\\
\PL{LIT}{}{Zrelov P.V. + 6 per.\\Ivanov V.V. + 10 per.\\Polanski A. + 2 per.}
%2
\item \PS{Methods and numerical algorithms for magnetic systems
modeling}{Akishin P.G.}{\null}\\
\PL{LIT}{}{Akishin P.G. + 1 per.\\Yuldashev O.I. + 1 per.}
%3
\item \PS{Software and computer complexes for experimental data processing}{Ivanov V.V.\\Zrelov P.V.}{\null}\\
\PL{LIT}{}{Dikusar N.D.\\Zrelov P.V. + 4 per.\\Ivanov V.V. + 6 per.\\
Kotov V.M. + 4 per.\\Ososkov G.A. + 2 per.\\Ivanchenko I.M. + 3 per.}
%4
\item \PS{Numerical algorithms and software for simulation of complex
physical systems}{Adam Gh.\\Puzynin I.V.}{\null}\\
\PL{LIT}{}{Adam Gh. \\ Adam S.\\Hayryan E.A. + 6 per. \\Amirkhanov I.V. + 8 per.\\
Bogolubsky I.L.\\Zemlyanaya E.V. + 1 per.\\Puzynin I.V. + 17 per.\\Puzynina T.P.\\
Serdyukova S.I.}
%5
\item \PS{Methods, algorithms and software of computer algebra}{Gerdt V.P.}{\null}\\
\PL{LIT}{}{Gerdt V.P. + 8 per.\\Kornyak V.V.}
%6
\item \PS{Computing tools of a new generation}{Ivanov V.V.\\Adam Gh.}{\null}\\
\PL{LIT}{}{Hayryan E.A. + 4 per.\\Gerdt V.P. + 2 per.\\Ivanov V.V. + 6 per.\\
Suzko A.A.\\Uzhinsky V.V.}
\end{stage-t}
\begin{intcoop}
\mtab{Armenia}{Yerevan}{YSU}
\mtab{}{}{IIAP NASA}
\mtab{}{Ashtarak}{IPR NASA}
\mtab{Austria}{Linz}{RISC}
\mtab{Australia}{Sydney}{Univ.}
\mtab{Belarus}{Minsk}{IM NASB}
\mtab{}{}{JIPNR-Sosny NASB}
\mtab{}{Brest}{BSTU}
\mtab{Belgium}{Brussels}{ULB}
\mtab{}{Liege}{ULg}
\mtab{Bulgaria}{Sofia}{IMech BAS}
\mtab{}{}{IMI BAS}
\mtab{}{}{INRNE BAS}
\mtab{}{}{SU}
\mtab{}{}{TU-Sofia}
\mtab{}{Rousse}{RU}
\mtab{Canada}{Edmonton}{U of A}
\mtab{}{Toronto}{IBM Lab}
\mtab{CERN}{Geneva}{}
\mtab{Chile}{Valparaiso}{UTFSM}
\mtab{Czech Republic}{Prague}{CTU}
\mtab{}{Rez}{NPI ASCR}
\mtab{Egypt}{Cairo}{AEA}
\mtab{}{Giza}{CU}
\mtab{Finland}{Turku}{UT}
\mtab{France}{Metz}{UPV-M}
\mtab{Georgia}{Tbilisi}{IC GAS}
\mtab{}{}{RMI GAS}
\mtab{Germany}{Berlin}{FU Berlin}
\mtab{}{}{HUB}
\mtab{}{Aachen}{RWTH}
\mtab{}{Darmstadt}{GSI}
\mtab{}{Giessen}{JLU}
\mtab{}{Halle}{MLU}
\mtab{}{Heidelberg}{Univ.}
\mtab{}{}{MPI-K}
\mtab{}{Julich}{FZJ}
\mtab{}{Kassel}{Uni Kassel}
\mtab{}{Marburg}{Univ.}
\mtab{}{Munich}{TUM}
\mtab{}{Rostock}{Univ.}
\mtab{}{Tubingen}{Univ.}
\mtab{Greece}{Athens}{Univ.}
\mtab{}{Thessaloniki}{AUTH}
\mtab{Italy}{Turin}{INFN}
\mtab{Japan}{Osaka}{Kansai Univ.}
\mtab{Kazakhstan}{Almaty}{INP NNC RK}
\mtab{}{}{PTI MS-NAS RK}
\mtab{Mexico}{Mexico}{IPN}
\mtab{Mongolia}{Ulaanbaatar}{NUM}
\mtab{}{}{SMCS NUM}
\mtab{Poland}{Warsaw}{FP WUT}
\mtab{}{}{SINS}
\mtab{}{Cracow}{AGH}
\mtab{}{Lodz}{SINS}
\mtab{}{Otwock-Swierk}{IAE}
\mtab{}{}{SINS}
\mtab{}{Rzeszow}{Univ.}
\mtab{Portugal}{Coimbra}{UC}
\mtab{Romania}{Bucharest}{IFIN-HH}
\mtab{}{}{UB}
\mtab{Russia}{Moscow}{CC RAS}
\mtab{}{}{IMM RAS}
\mtab{}{}{ITEP}
\mtab{}{}{MEPhI}
\mtab{}{}{MIREA}
\mtab{}{}{MSU}
\mtab{}{}{PFUR}
\mtab{}{Belgorod}{BelSU}
\mtab{}{Protvino}{IHEP}
\mtab{}{Puschino}{IMPB RAS}
\mtab{}{}{ITEB RAS}
\mtab{}{Saratov}{SSU}
\mtab{}{St. Petersburg}{FIP}
\mtab{}{}{PDMI RAS}
\mtab{}{Tver}{TvSU}
\mtab{Slovak Republic}{Kosice}{IEP SAS}
\mtab{}{}{TU}
\mtab{}{Presov}{PU}
\mtab{South Africa}{Cape Town}{UCT}
\mtab{}{Pretoria}{UP}
\mtab{Switzerland}{Zurich}{ETH}
\mtab{Sweden}{Stockholm}{KTH}
\mtab{}{Lund}{LU}
\mtab{Taiwan}{Taipei}{AS}
\mtab{Tajikistan}{Dushanbe}{TGNU}
\mtab{}{Khojent}{KSU}
\mtab{Ukraine}{Kiev}{BITP NASU}
\mtab{}{}{IM NASU}
\mtab{}{Kharkov}{ILTPE NASU}
\mtab{}{}{KFTI NASU}
\mtab{United Kingdom}{Manchester}{Univ.}
\mtab{}{Plymouth}{Univ.}
\mtab{USA}{Louisville, KY}{UofL}
\mtab{}{Argonne, IL}{ANL}
\mtab{Vietnam}{Hanoi}{VNU}
\end{intcoop}