                                    
\TN{02--2--1123--2015/2016}{1}{\tsnew}
{JINR's Participation at the BES-III Physics Research Program}
{A.S.~Zhemchugov}
%
\TC{ China,  Russia.}

\TA The BES-III experiment at the electron-positron collider BEPC-II started
its operation in the Institute of High Energy Physics (Beijing, China) in 2008.
 The main tasks of the experiment are the studies of charmonium physics, physics
 of charmed mesons, tau-leptons and light hadron spectroscopy.	

%%\vspace*{4mm}

{\bf Expected main results in 2015:
}

\begin{itemize}
\item BES-III data analysis.
\item Development of offline software and analysis tools
\item Development of the distributed computing system.
\end{itemize}

%%\begin{project}
%%%\item \PList{SANC}{D.Yu.~Bardin}{1}{2003}{2015}
%%\item \PList{BES-III}{A.S.~Zhemchugov}{1}{2007}{2016}

%%\end{project}

%%%\vspace*{8mm}

\begin{stage}
\item [] \PS{BES-III Project}{A.S.~Zhemchugov}{\psinp}
\PL{DLNP}{}{I.R.~Boyko, D.V.~Dedovich, Yu.A.~Nefedov, G.A.~Shelkov, I.I.~Denisenko, E.A.~Boger, O.L.~Fedorov, O.V.~Bakina}
\PL{BLTP}{}{ V.V.~Bytev, O.V. Teryaev }
\PL{LIT}{}{V.V.~Korenkov, A.V.~Uzhinsky, S.D.~Belov, I.S.~Pelevanyuk, O.V.~Ustimenko, V.V.~Trofimov}

\end{stage}
%%%\vspace*{8mm}

\begin{intcoop}
%\mtab {}{Shumen}{US}
%\mtab{ CERN}{Geneva}{CERN}
\mtab{China}{Beijing}{IHEP CAS}
\mtab{Russia}{Gatchina}{PNPI}
\mtab{}{Novosibirsk}{BINP SB RAS}
\mtab{}{Irkutsk}{ISU}

\end{intcoop}


%%\newpage

\TN{02--2--1098--2010/2015}{1}{\tscom}
{Study of Processes with Symmetry Violation}
{A.S.~Kurilin}

\TC{Belarus, Japan, Republic of Korea, Russia, Slovakia, Taiwan, Ukraine, USA.}
 
\TA  Test of Standard Model predictions.
 Investigation of rare decays of K-mesons. Search for the
 $K^0_L \rightarrow \pi^0 \nu \bar{\nu}$  decay with direct
 CP violation in experiment at JPARC.  
 
%%\vspace*{4mm}
{\bf Expected main results in 2015:
}

\begin{itemize}
\item Development of GEANT4--based simulation, DAQ and data analysis
      software.

\item Design and test of new detectors.

\item Data taking and analysis of new data for the rare decay of $K^0_L$.

\item Data taking on KOTO setup at JPARC  (Japan).

\end{itemize}


\begin{stage}
\item \PS{Search for the $K^0_L \rightarrow \pi^0 \nu \bar{\nu}$\\
decay (KOTO experiment at JPARC) }{A.S.~Kurilin}{\pspt\\ \psdt\\ \psda}
\PL{DLNP}{}{V.A.~Baranov, V.A.~Bednyakov, 
  S.V.~Podolsky,  A.G.~Dolbilov, E.S.~Kuzmin, A.S.~Moiseenko, Yu.Yu. Stepanenko, S.Yu. Porokhovoy,
  V.M.~Romanov }
\PL{BLTP}{}{D.I.~Kazakov, A.V.~Gladyshev }
\PL{VBLHEP}{}{A.I.~Malakhov, S.J.~Sychkov}
\PL{FLNP}{}{V.N. Shvetsov, P.V. Sedyshev }
\end{stage}

\begin{intcoop}
\mtab{ Belarus}{Gomel}{ GSU}
\mtab{}{Minsk}{NC PHEP BSU}
\mtab{}{}{BSU}
\mtab{ Japan}{Ibaraki}{Ibaraki Univ.}
\mtab{}{Kyoto}{Kyoto Univ.}
\mtab{}{ Osaka}{OCU}
\mtab{}{}{RCNP}
\mtab{}{ Saga}{Saga Univ.}
\mtab{}{Tsukuba}{ KEK}
\mtab{}{Yamagata}{Yamagata Univ.}
%\mtab{Poland}{Krakow}{JU}
\mtab{Republic of Korea}{Pusan}{PNU}
\mtab{}{Chongju}{CBNU}
\mtab{}{Seoul}{SNU}
\mtab{ Russia}{Moscow}{GPI RAS}
\mtab{}{}{ARRICT}
%\mtab{}{}{NIKIET}
\mtab{}{}{SINP MSU}
%\mtab{}{Moscow, Troitsk}{INR RAS}
%\mtab{}{Protvino}{IHEP}
\mtab{Slovakia}{Kosice}{IEP SAS}
\mtab{ Ukraine}{Kharkov}{KFTI NASU}
\mtab{USA}{East Lansing, MI}{MSU}
\mtab{ }{Chicago, IL}{UChicago}
\mtab{}{Tempe, AZ}{ASU}
\mtab{Taiwan}{Taipei}{NTU}

\end{intcoop}


%%\newpage

\TN{02--2--1080--2009/2015}{1}{\tscom}
{Lifetime Measurement of \boldmath $\pi^+\pi^-$ and $\pi^\pm K^\mp$ Atoms \\
to Test Low-Energy QCD Precise Predictions}
{L.G.~Afanasyev}
%%%%\PLDDD{L.L.~Nemenov}

\TC{CERN, Czech Republic, Italy, Japan, Romania, Russia, Spain,  Switzerland.}

\TA  The experiment aims to measure  the lifetime of
 $\pi^+\pi^-$  atoms ($A_{2 \pi}$), observe $\pi K$ atoms ($A_{\pi K}$), and
 measure their lifetime using the 24~GeV proton beam. The precise
 measurement of these quantities will enable us to determine the
 combination of $s$-wave pion--pion |$a_0 - a_2$| and pion--kaon
 |$a_{1/2}-a_{3/2}$| scattering lengths (with isospin 0, 2 and 1/2, 3/2,
 respectively) in a model-independent way. The precision of $A_{2 \pi}$
 lifetime measurement will be better than 6\% and the difference
 |$a_0 - a_2$| will be determined within 3\% or better. The accuracy of
 $A_{\pi K}$ lifetime measurement will be at the level of 20\% and the
 difference |$a_{1/2}-a_{3/2}$|  will be determined at the level of 10\%.
 Low-energy QCD predicts these values with an accuracy about 2\% for the
 pion--pion scattering lengths and about 10\% for the $\pi K$ scattering
 lengths. The pion--pion and pion--kaon scattering lengths have never been
 verified with the experimental data with the same level of precision. For this
 reason the proposed measurements will be a crucial check of the low-energy
 QCD predictions and our understanding of the nature of the QCD vacuum.
 
%%\vspace*{4mm}

{\bf Expected main results in 2015:}
\begin{itemize}
%\item Completion of the processing of the 2008-2010 data for observation and lifetame measurement of
%$\pi^{\pm}K^{\mp}$ atom. Publishing results.

\item Preparation of the letter of intend for investigation of $\pi^{\pm}K^{\mp}$ and  $\pi^+ \pi^-$ atoms
at the SPS accelerator, CERN.

\item Publishing of the result on observation of the long-lived states of $\pi^+ \pi^-$ atom basing on 2012 data.

\item  Processing of the data collected in 2011-2012 for measurement of the multiple scattering in
 thing foils with accuracy better than 1\%.

\item Publication of results on lifetime measurement of $\pi^+ \pi^-$ atom basing on 2008-2010 data.
%Completion of the processing of the for.
%Preparation of publication.
\end{itemize}
 
\begin{stage}
\item[]  \PS{Experiment DIRAC}{L.G.~Afanasyev}{\psda}
\PL{DLNP}{}{ M.V.~Zhabitsky, A.V.~Dudarev, V.V.~Kruglov, V.V.~Karpukhin, E.~Kulish, A.V.~Kulikov, 
  L.L.~Nemenov, M.V.~Nikitin }
\PL{LIT}{}{P.V. Zrelov, O.O. Voskresenskaya, L.Yu. Kruglova}
\end{stage}

\begin{intcoop}
\mtab{ CERN }{Geneva}{CERN}
\mtab{ Czech Republic}{Prague}{CTU}
\mtab{}{}{IP ASCR}
\mtab{}{Rez}{NPI ASCR}
\mtab{ Italy}{Frascati}{INFN LNF}
\mtab{}{ Messina}{UniMe}
\mtab{}{Trieste}{INFN}
\mtab{ Japan}{Kyoto}{KSU}
\mtab{}{Tokyo}{TMU}
\mtab{}{Tsukuba}{KEK}
\mtab{ Romania}{Bucharest}{IFA}
\mtab{ Russia}{Moscow}{SINP MSU}
\mtab{}{Protvino}{IHEP}
\mtab{Spain}{Santiago de Compostela}{USC}
\mtab{ Switzerland}{Bern}{Uni Bern}
%\mtab{}{ Basel}{Uni Basel}
\mtab{}{ Zurich}{UZH}

\end{intcoop}

%%\newpage


\TN{02--0--1081--2009/2016}{1}{\tsprg}
{A~T~L~A~S. \\Upgrade of the ATLAS Detector and
 Physics Research at the LHC }
{ V.A.~Bednyakov}
\TLDs{E.V.~Khramov \\ A.P.~Cheplakov}
\TC{Armenia, Azerbaijan, Belarus, Canada, CERN, Czech Republic,  France, Germany, Georgia, Greece, Israel, 
 Italy, Netherlands, Russia, Slovakia, Spain, USA, Uzbekistan.} 

 \TA Many-sided and comprehensive investigations of superhigh-energy (7--14~TeV)
 proton scattering at the Large Hadron Collider with the ATLAS facility
 (created at the previous stage of the project) will yield utterly new and
 unique experimental data. Their analysis will allow solution to the most
 profound physical problems fundamentally important for world outlook.<br><br>

JINR researchers will take part in solution of some of these
problems within the project. Among the most important of them are
the clarification of the origin of the elementary particle mass
(Higgs mechanism) and search for and investigation of
supersymmetry, which will allow an insight into the nature of
galactic dark matter and the character of the evolution of our
Universe. Other important problems are determination of the
applicability boundaries of the modern standard model of
elementary particles and observation of evidence for new physical
phenomena, such as additional space dimensions or previously
unknown particles and interactions. In addition, JINR researchers
will get new results allowing more specific knowledge as to the
properties of the already known elementary particles such as the W
and Z bosons, the top quark, and others.<br><br>

Implementation of this project aimed at solving highly important
scientific problems will result in getting unique applied data.<br><br>

The "by-products" worth noting are development, debugging, and
experience in operation of systems for remote monitoring of highly
complicated devices and development and practical use of the
distributed compu\-tation system (grid) in a long-term, full-scale
experiment.

%%\vspace*{4mm}
{\bf Expected main results in 2015:}
\begin{itemize}

\item Participation in the LHC and ATLAS detector maintenance and upgrades.
Participation in LHC and ATLAS restart.
%Operation of the ATLAS detector and the remote monitoring system at JINR.

\item Data development and analysis of the ATLAS data. The new physical results to be
 obtained in  investigations of
 some key processes of the Standard Model,exotic physics, search for SUSY.

\item Development of the ATLAS physics programme: simulation of physical processes,
 participation in the ATLAS working group, etc.
\item Work on the modernization project of the ATLAS detector, including the toroidal
magnets, hadron calorimeters and muon spectrometer.
\end{itemize}

%%\begin{project}
%%\item \PList{ATLAS. Physics. }{E.V.~Khramov}{1}{2010}{2019}
%%\item \PList{Upgrade of the ATLAS Detector}{A.P.~Cheplakov}{1}{2013}{2015}
%%\item \PList{SANC}{D.Yu.~Bardin}{1}{2003}{2015}
%%\end{project} 

\begin{stage}
\item \PS{Experiment ATLAS}{V.A.~Bednyakov\\E.V.~Khramov\\A.P.~Cheplakov}{\pstp}
\PL{DLNP}{\\V.A. Bednyakov, J.A. Budagov,\\ N.A.~Russakovich, G.A. Chelkov}{A.L.~Gongadze,  
 I.R.~Boyko, M.A.~Demichev, Z.V.~Krumshteyn, Yu.A.~Koultchitski, I.A.~Minashvili, M.I.~Gostkin,   
  G.L.~Glonti, D.V.~Dedovich, Yu.A.~Nefedov, D.V.~Kharchenko,  
 Yu.A.~Usov, M.Yu.~Kazarinov, V.A.~Kolesnikov, S.N.~Malyukov, V.Yu.~Batusov,  V.V.~Lyubushkin, R.R.~Sadykov, M.V.~Chizhov, 
 V.V.~Glagolev, P.V.~Tereshka, Z.U.~Usubov, Yu.P.~Ivanov, S.N.~Karpov, Z.M.~Karpova, M.V.~Lyablin,
 A.B.~Lazarev, G.I.~Lykasov, A.A.~Sapronov, A.N.~Shalyugin, 
 M.M.~Shiyakova, V.B.~Vinogradov, A.C.~Zhemchugov, S.N.~Baranov, Yu.L.~Vertogradova,
 A.V.~Ershova, N.~Huseinov, L.K.~Gladilin, I.V.~Eletskikh, T.V.~Lyubushkina, E.M.~Plotnikova, E.D.~Uglov, Yu.I.~Davydov, V.~Elkin,
 S.A.~Kotov, V.G.~Kruchonok, N.P.~Kuznetsov, I.N.~Potrap}
\PL{VBLHEP}{\\A.P. Cheplakov, V.D. Peshekhonov}{N.~Dzhavadov, 
  E.A.~Ladygin, F.N.~Ahmadov, V.V.~Kukhtin, V.N.~Pozdnyakov, B.G.~Shaykhatdenov, 
  N.G.~Fadeev, L.A.~Merkulov, V.V.~Myalkovsky, E.V.~Serochkin, A.A~Soloshenko, N.I.~Zimin, A.A.~Savenkov, Yu.A.~Filippov}
\PL{LIT}{\\V.V. Korenkov, P.V. Zrelov}{I.N.~Aleksandrov, N.I.~Gromova, A.V.~Yakovlev, V.M.~Kotov,  V.N.~Shigaev, M.A~Mineev,
  D.A.~Oleynik, A.S.~Petrosyan}
 \PL{BLTP}{\\D.I.~Kazakov}{A.V.~Gladyshev, A.V.~Bednyakov, N.I.~Kochelev, A.F.~Pikelner, O.B.~Teryaev}
\PL{FLNP}{\\S.A.~Kulikov}{M.V.~Bulavin, E.N.~Kulagin, E.P.~Shabalin}

\item \PS{SANC Project}{D.Yu.~Bardin}{\psinp}
\PL{DLNP}{}{L.V.~Kalinovskaya, A.A.~Sapronov, P.~Christova, R.R.~Sadykov, E.D.~Uglov, V.A.~Kolesnikov, L.A.~Rumyantsev}
\PL{BLTP}{}{A.B.~Arbuzov, S.G.~Bondarenko}

\end{stage}
 
\begin{intcoop}
\mtab{ Armenia}{Yerevan}{YerPhI}
\mtab{ Azerbaijan}{Baku}{IP ANAS}
\mtab{ Belarus}{Minsk}{IP NASB}
\mtab{}{}{NC PHEP BSU}
\mtab{}{}{JIPNR-Sosny NASB}
\mtab{}{Gomel}{GSTU}
%\mtab{}{}{CNTDI}
\mtab{ Canada }{Vancouver}{TRIUMF}
\mtab{}{Montreal}{UdeM}
\mtab{ CERN }{Geneva}{CERN}
\mtab{ Czech Republic}{Prague}{CU}
\mtab{ France}{Clermont-Ferrand}{LPC-CF}
\mtab{}{Orsay}{LAL}
\mtab{ Germany}{Munich}{MPI-P}
\mtab{}{Zeuthen}{DESY}
\mtab{ Georgia}{Tbilisi}{HEPI-TSU}
\mtab{Greece}{Athens}{UoA}
\mtab{ Israel}{Rehovot}{WIS}
\mtab{ Italy}{Pisa}{INFN}
\mtab{ Netherlands}{Amsterdam}{NIKHEF}
\mtab{ Russia}{Moscow}{LPI RAS}
\mtab{}{}{ITEP}
\mtab{}{}{MSU}
\mtab{}{Protvino}{ IHEP}
\mtab{ Slovakia}{Bratislava}{CU}
\mtab{}{}{IP SAS}
\mtab{ Spain}{Barcelona}{ IFAE}
\mtab{ USA}{Argonne, IL}{ANL}
\mtab{ Uzbekistan}{Samarkand}{SSU}
\end{intcoop}

%%\newpage



\TN{02--2--1124--2015/2017}{1}{\tsnew}
{ Sarch for New Physics in Experiments with the Fermilab High-Intensity Muon Beams }
{V.V.~Glagolev}
%%\PLDDD{J.A.~Budagov}

\TC{Belarus, Bulgaria, Georgia, Italy, Russia, Slovakia, USA, Ukraine.}

\TA The muon anomalous magnetic moment $a_{\mu}$ can be measured and computed to high precision.
 The comparison between experiment and the SM  therefore provides a sensitive search for New Physics (NP).
 At present, both measurement and theory have sub-part-per-million (ppm) uncertainties, and the "g-2 test"
 is being used to constrain SM extensions. The difference between experiment and theory,
 $\Delta a_{\mu}(Expt-SM) = (255 \pm 80) \times 10^{-11}$ $(3,2 \sigma)$, is a highly cited result and a possible
 harbinger of new TeV-scale physics. Potential explanations of the deviation include: supersymmetry,
 lepton substructure, dark matter loop etc., all well motivated by theory and consistent with other experimental
 constraints. Fermilab experiment has a plan to reduce the experimental uncertainty by a factor of 4 or more.
 A precise g-2 test, no matter where the final value lands, will sharply discriminate among models and will
 enter as one of the central observables in a global analysis of any SM extensions.<br><br>

 The Mu2e experiment at Fermilab is a dedicated search for the CLFV process $\mu^{-} N\rightarrow e^{-} N$,
 which is the coherent conversion
 of a muon into an electron in the vicinity of a nucleus. Once neutrinos masses are included, the process is
 allowed but effectively still absent since the rate is proportional to  $(\Delta m^2_{ij}/M^2_W)^2 $ ,
 where $ \Delta m^2_{ij}$  is the mass difference
 squared between i-th and j-th neutrino mass eigenstates, and $M_W$  is the mass of the W-boson.
 The predicted rates for the $ \mu^{-}N\rightarrow e^{-}N$  and $\mu^{+}\rightarrow e^{+}\gamma $
 CLFV processes are less than $10^{-50}$ each. This makes this process a very
 theoretically clean place to search for NP effects. In many NP models that include a description of neutrino
 mass, the rates for these processes are enormously enhanced so that they occur at a level to which Mu2e
 experiment will have sensitivity.

%%\vspace*{4mm}

{\bf Expected main results in 2015:}
\begin{itemize}
\item Simulation to define optimal crystal  type and sizes for e.m. calorimeter of the Mu2e experiment.
\item Tests of the different type (LYSO, CsI, Baf2) e.m. calorimeter  elements  on the gamma sources and
electron beam.
\item Tests of the extruded scintillation strips different geometry and manufacture with wave length shifter
fibers readout  to optimize the final version of counters.
\item Creation of the working version of the on-line control  and data visualization program for Muon g-2
experiment and its integration in the common DAQ system.
\item Performing R@D  for  choosing optimal tracker detector element for Muon g-2 experiment.

\end{itemize}

%%\begin{project}
%%\item \PList{Sarch for new physics in experiments with the Fermilab high-intensity muon beams }{V.V.~Glagolev }{1}{2015}{2017}

%%\end{project}

\begin{stage}
\item \PS{Experiment Mu2e}{V.V.~Glagolev}{\pspt\\ \psinp}
\PL{DLNP}{}{A.M.~Artikov, N.V.~Atanov, O.S.~Atanova,
N.S.~Azaryan, V.Yu.~Baranov, V.Yu.~Batusov, J.A.~Budagov, D.Sh.~Chokheli, Yu.I.~Davydov, D.L.~Demin, V.B.~Flyagin,
D.S.~Guskov, Yu.N.~Kharzheev, V.I.~Kolomoets, S.M.~Kolomoets,  M.V.~Lyablin, Yu.A.~Koultchitski,
V.M.~Romanov, A.V.~Sazonova,   A.N.~ Shalóugin, A.V.~Simonenko, S.N.~Studenov, I.A.~Suslov,  A.K.~Suhanova, I.V.~Titkova, V.V.~Tereschenko,
S.V.~Tereschenko, Z.U.~Usubov}
\PL{BLTP}{}{D.I.~Kazakov, G.A.~Kozlov, O.V.~Tarasov}
\PL{LIT}{}{V.V.~Korenkov, V.V.~Uzhinsky}
\PL{VBLHEP}{}{A.~Galoyan}

\PS{Experiment Muon g-2}{N.V.~Khomutov}{\pspt \\ \psinp}
\PL{DLNP}{}{V.A.~Baranov, V.N.~Duginov,  K.I.~Gritsaj,  A.S.~Korenchenko,
N.P.~Kravchuk,  N.A.~Kuchinsky,  T.N.~Mamedov , A.I.~Rudenko, V.P.~Volnykh}
\PL{VBLHE}{}{S.A.~Movchan}
\PL{LRB}{}{V.A. Krylov}
\end{stage}

\begin{intcoop}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{}{}{"INTEGRAL"}
\mtab{Bulgaria}{Sofia}{SU}
%\mtab{Chile}{Valparaiso}{Univ.}
\mtab{Georgia}{Tbilisi}{HEPI-TSU}
%\mtab{Greece}{Athens}{UoA}
\mtab{Italy}{Pisa}{UniPi}
\mtab{}{Frascati}{INFN LNF}
\mtab{Russia}{Moscow, Troitsk}{INR RAS}
\mtab{}{Gatchina}{PNPI}
\mtab{Slovakia }{Bratislava}{IP SAS}
\mtab{}{}{CU}
%\mtab{USA}{Argonne, IL}{ANL}
\mtab{USA}{Batavia, IL}{Fermilab}
\mtab{}{Charlottesville, VA}{UVa}
\mtab{}{Lexington, KY}{UK}
\mtab{Ukraine}{Kharkov}{ISM NASU}

\end{intcoop}

%%%\newpage
\TN{02--2--1099--2010/2015}{1}{\tscom}
{Study of Neutrino Oscillations }
{D.V.~Naumov\\ A.G.~Olshevskiy} 
%\TLD{O.Yu.~Smirnov}

\TC{ Czech Republic, Germany, Japan, Italy, Turkey, USA.}

\TA 
\begin{itemize}
\item Measurement of the $\theta{_1}{_3}$ neutrino mixing angle and $\Delta m^2_{ee}$ squared mass difference
in Daya Bay experiment.
%Search for long-baseline neutrino oscillation and study of
% neutrino oscillation parameters with the OPERA detector in the CNGS beam (CERN--Gran
% Sasso) OPERA project.

\item  Measurement of the solar neutrino fluxes in Borexino experiment, search for the sterile neutrino state.
%Direct solar neutrino flux measurements with the BOREXINO detector -- phase-II experiment.

\item Study of the neutrino oscillations in OPERA experiment.

\item Neutrino mass hierarchy determination and measurement of CP violation phase of the neutrino mixing matrix
in JUNO and NOvA experiments.

\item R&D for the new photo-detectors and detector equipment for the neutrino experiments.

\item Improving of the precision of direct solar neutrino flux measurements with the Borexino detector, phase-II experiment.
%Improving of the precision of the neutrino mixing angle measurement
% in the Daya Bay experiment.
\end{itemize}

%%\vspace*{4mm}

{\bf Expected main results in 2015:
}

\begin{itemize}

\item Development of our own selection of inverse beta decay (IBD) events and of various backgrounds to IBD events in the Daya Bay
experiment. Study of background energy spectra. Reactor antineutrino flux and rate measurement in the Daya Bay experiment.
%Scanning and analysis of the OPERA nuclear
%emulsion at JINR.

\item Study of quantum decoherence effects in neutrino oscillations taking into account Daya Bay data.
Search for light sterile neutrino in the Daya Bay experiment.
%Software development for the Target Tracker data analysis. Development of
% the Brick Finding software, analysis of the electronic detector data
% and event vertex location.

\item Simulation, reconstruction and analysis software development for JUNO experiment.
%Continuation of the data taking with the BOREXINO detector.

\item Feasibility study of Top Muon Veto detector based on re-using of OPERA Target Tracker detector.
%Improvement of the   position reconstruction algorithm for the BOREXINO detector.

\item Development and tests of high voltage system for JUNO PMT.
%The study  seasonal variations of the solar neutrino flux.

\item Software development for the global analysis of neutrino oscillation data with the primary goal of combining 
reactor and accelerator neutrino data to measure the mass hierarchy.
%Precise measurement of the pp-neutrino flux with total errors down to 15\%.

\item Development of the event selection algorithms for the NOvA experiment.
%Improvement of the current results on the effective solar neutrino magnetic moment.

 \item Continuation of the data taking with the Borexino detector. Improvement of the position reconstruction algorithm.
 %Improvement of the current result on the reactions.

\item Measurements with artificial neutrino source within sterile neutrino search project SOX (Borexino).
%Development of Monte Carlo software for
%background simulation in the Daya Bay experiment.

\item Measurement or setting limits of the solar neutrino flux from the CNO cycle (Borexino).
%Participation in data analysis for $\theta_{13}$ mixing angle measurement in the Daya Bay experiment.

\item Improving of the current results on the effective solar neuntrino magnetic moment and on the $e\rightarrow \nu\gamma$
reaction (Borexino).

\item Search for the neutrino interactions by scanning and analysing nuclear emulsions from OPERA detector in JINR. 
Search for the new tau-neutrino candidates in OPERA experiment. Software development and data analysis for electron neutrino
search in OPERA experiment.

\item OPERA detector decommission.
\end{itemize}

%%\begin{project}
%%\item \PList{BOREXINO}{O.Yu.~Smirnov}{1}{1996}{2015}
%%\item \PList{Daya Bay/JUNO}{D.V.~Naumov }{1}{2009}{2017}
%%\item \PList{NOvA}{A.G.~Olshevskiy}{1}{2015}{2017}
%%\item \PList{OPERA}{Yu.A.~Gornushkin}{1}{2010}{2015}
%%\end{project}

\begin{stage}

\item \PS{Experiment BOREXINO }{O.Yu.~Smirnov}{\psdt}
\PL{DLNP}{}{K.A. Fomenko, D.V. Korablev, A.P. Sotnikov }

\item \PS{Daya Bay/JUNO Project}{D.V.~Naumov \\ M.O.~Gonchar}{\psdt \\ \pspt}
\PL{DLNP}{}{I.V.~Butorov, M.O.~Gonchar, M.A.~Dolgareva, E.A.~Naumova, I.B.~Nemchenok, A.G.~Olshevskiy,
A.V.~Chukanov, D.V.~Taichenachev, N.V.~Anfimov, S.V.~Biktemerova, Yu.A.~Gornushkin, S.G.~Dmitrievsky, A.V.~Krasnoperov,
Z.V.~Krumshtein, N.A.~Morozov, A.V.~Rybnikov, A.B.~Sadovsky, A.S.~Selunin, O.Yu.~Smirnov, K.A.~Fomenko, D.V.~Fedoseev}
 
\item \PS{NOvA Project}{A.G.~Olshevskiy \\ O.B.~Samoylov}{\psdt}
\PL{DLNP}{}{N.V.~Anfimov, A.E.~Bolshakova, S.G.~Dmitrievsky, A.G.~Dolbilov, A.A.~Dolmatov, Yu.A.~Gornushkin, Ch.~Kullenberg,
D.V.~Naumov, A.B.~Sadovsky,  I.M.~Shandrov, A.S.~Sheshukov, A.P.~Sotnikov}
\PL{BLTF}{}{S.M.~Bilenky, K.S.~Kuzmin, V.A.~Matveev, V.A.~Naumov, O.N.~Petrova}
\PL{LIT}{}{ V.V.~Korenkov + 2 pers.} 
 
\item \PS{Experiment OPERA }{Yu.A.~Gornushkin }{\psdt}
\PL{DLNP}{}{S.G.~Dmitrievsky, Z.V.~Krumshtein, A.G.~Olshevskiy, S.G.~Zemskova, A.V.~Chukanov,
 A.B.~Sadovsky,  A.S.~Sheshukov, A.A.~Nozdrin}
\PL{VBLHEP}{}{Yu.P.~Petukhov}
\PL{LIT}{}{ G.A.~Ososkov}

\item \PS{Development of new photodetectors and the equipment for application in registering systems 
of neutrino experiments}{A.G.~Olshevskiy}{\pspt}
\PL{DLNP}{\\Z.V.~Krumshtein}{A.~Antoshkin, N.V.~Anfimov, T.V.~Rezinko, A.V.~Rybnikov, A.V.~Selunin, V.V.~Chalyshev, I.E.~Chirikov-Zorin,
D.V.~Fedoseev}
\PL{VBLHEP}{\\Z.Ya.~Sadygov}{T.Yu.~Bokova, I.A.~Tyapkin, B.~Marinova}
\PL{LIT}{}{ G.A.~Ososkov}
\end{stage}

\begin{intcoop}

\mtab{Germany}{Hamburg}{Univ.}
\mtab{Czech Republic}{Prague}{CU}
\mtab{Italy}{Salerno}{INFN}
%\mtab{China}{Guangzhou}{SYSU}
\mtab{USA}{Indianapolis, IN}{IUPUI}
\mtab{}{Batavia, IL}{Fermilab}
\mtab{}{Cambridge, MA}{Harvard Univ.}
\mtab{Turkey}{Ankara}{METU}
\mtab{Japan}{Tokyo}{Toho Univ.}
%\mtab{Ukraine}{Kharkov}{ISC NASU}
                                                                              
\end{intcoop}


\TN{02--0--1108--2011/2016}{1}{\tsprg} 
{Experiment PANDA at FAIR}{A.G.~Olshevskiy }
\TLDs{G.D.~Alexeev\\A.S.~Vodopyanov }

\TC{Belarus, CERN, Czech Republic, Germany, Italy, Russia, Ukraine. }

\TA The study of the exotic nuclear-matter states and
nucleon structure in the PANDA experiment at FAIR.

%%\vspace*{4mm}

{\bf Expected main results in 2015:
}
\begin{itemize}
\item Inclusion of MC generators into the PANDA software and optimization of the event analysis.
\item Calculations and coordination of the work for the production of the superconducting solenoid sub-systems.
%\item Preparation of the documentation for magnet production.
\item Preparation of the technical specifications for the production of the PANDA muon system.
\item Test of MDT at CERN PS.
\end{itemize}

%%\begin{project}
%%\item \PList{PANDA}{A.G.~Olshevskiy}{1}{2011}{2017}
%%\end{project}


\begin{stage}

\item \PS{PANDA Project}{ A.G.~Olshevskiy}{\pstp}
\PL{DLNP}{\\G.D.~Alexeev}{V.M.~Abazov, N.B.~Skachkov, N.~Angelov, D.B.~Pontekorvo,
  A.G.~Samartsev, A.N.~Skachkova,  V.V.~Tokmenin}
\PL{VBLHEP}{\\A.S.~Vodopyanov}{E.A.~Strokovsky, M.G.~Sapozhnikov,
 V.X.~Dodokhov, E.K.~Koshurnikov, M.Yu.~Barabanov, V.A.~Arefev, V.I.~Astakhov, A.A.~Efremov, V.I.~Lobanov,
 Yu.Yu.~Lobanov, P.V.~Nomokonov, I.A.~Alex, Yu.N.~Rogov, R.A.~Salmin, A.A.~Feshchenko, A.S.~Galoyan}
\PL{LIT}{}{Gh.~Adam, V.V.~Uzhinsky }
\PL{BLTP}{}{A.S.~Sorin, O.V.~Teryaev, A.V.~Efremov}

\item \PS{Development of MDT two-\\coordinate readout including\\ MDT design, electronics and prototype tests}{ G.D.~Alexeev}{\pspt}
\PL{DLNP}{}{V.M.~Abazov, A.G.~Samartsev, V.V.~Tokmenin, V.A.~Malyshev, A.A.~Piskun, S.A.~Kutuzov, L.S.~Vertogradov, Yu.A.~Yatsunenko, 
Yu.A.~Kozhevnikov, N.T.~Zhuravlev}
\end{stage}

\begin{intcoop}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{CERN}{Geneva}{CERN}
\mtab{Czech Republic}{Prague}{CU}
\mtab{Germany}{Darmstadt}{GSI}
\mtab{Italy}{Turin}{UniTo}
\mtab{Russia}{Protvino }{IHEP}
\mtab{}{Dubna}{BSINP MSU}
\mtab{Ukraine}{Kharkov}{ISM NASU}

\end{intcoop}


\TN{02--2--1125--2015/2017}{2}{\tsnew}
{Astrophysical Studies in the Experiment TAIGA }
{L.G.~Tkatchev}
\TLD{V.M.~Grebenyuk}

\TC{ Czech Republic, Germany, Japan, Italy, Mexico, Republic of Korea, Romania, Russia, Ukraine. }
\TA
\begin{itemize}
\item The main topic of multi-messenger TAIGA array are Gamma-ray astronomy, charged cosmic ray physics\\ and particle
 physics. Gamma-ray astronomy - one of the most intriguing questions in high-energy astropar-\\ticle physics
is a search for galactic objects for accelerating of particles up to PeV-energies (thr so-called Pevatrons);
VHE spectra of known sources: where do they stop; absorption in IR and CMB; diffuse emission from galactic
plane and local supercluster.Charged cosmic ray physics -- the energy spectrum and mass composition measurements from
$10^{14}$ to $10^18$ eV. Particle physics - axion/photon conversion; hidden photon/photon oscillations; Lorentz invariance
violation; pp cross-section measurement; search for quark-gluon plasma phenomena.

\item The TUS space experiment has been proposed to measure the energy spectrum, composition and angular
 distribution of the Ultra High Energy Cosmic Rays (UHECR) at
 $E \approx 10^{19}-10^{20}$~eV, to study the region beyond the GZK cutoff.
  Existence of these particles is beyond the Standard Model of particle physics and is of great interest.
  The study from the orbit is much more effective in
  comparison with the ground-based detectors. The existing world statistics
 is assumed to be increased by a factor of 2--3 during 3 years of the global data
 taking. The TUS detector will make it possible to study  UHECP
 neutrino Extensive Air Showers (EAS) from the space orbit.

\item The aim of the NUCLEON Project is direct CR measurements in the energy range
 10$^{11}$-10$^{15}$~eV and the atomic charge range up to Z$\approx$40 in the near--Earth
 space to solve mainly the "knee" problem in the CR spectrum.  The CR phenomena in this
 energy region are investigated in terrestrial experiments by measurement
 of EAS parameters or in
 balloon or space experiments. Below $\sim 10^{14}$~eV the spectrum and
 composition are known from direct observation with detectors
 placed in balloons and earth satellites. However, at higher energies the CR flux
 is smaller and more difficult for direct and needs observation.
 Precise measurement of the CR composition and anisotropy will help to test the existing
 theoretical concepts and will become a basis for further studies.

\end{itemize}
%%\vspace*{4mm}

{\bf Expected main results in 2015:
}

\begin{itemize}
\item Completion of the complex tests of the  TUS apparatus.

\item Participation in the data taking of the TUS experiment.

\item Participation in  the TUS data off-line analysis.

\item Test of the fluorescent datactor for ŇÓÍĘŔ array.

\item Production and test of the calibration system for TUS detector on the Earth orbit.

%\item Completion of the complex tests of the NUCLEON trigger system.

\item Development of the MC simulation program for the NEUTRONYI detector at the Moon surface.
% Development of on-line data handling programs.
Parti-\\cipation in the avant-project preparation of the NEUTRONYI detector.

\item Participation in the data taking of the NUCLEON experiment.
\end{itemize}

%%\begin{project}
%%\item [] \PList{TAIGA }{L.G.~Tkatchev}{2}{2015}{2017}
%%%\item \PList{TUS }{L.G.~Tkatchev}{1}{2012}{2014}
%%%\item \PList{NUCLEON }{L.G.~Tkatchev}{2}{2005}{2011}
%%\end{project}

%%\vspace*{4mm}
\begin{stage}

\item  \PS{Experiment TAIGA }{L.G.~Tkatchev}{\psinp}
\PL{DLNP}{}{V.M. Grebenyuk, S.Yu. Porokhovoy, A.V.~Tkachenko, F.F.~Grinyuk,
  M.~Slunechka, V.~Slunechkova,  N.~ Zaikova,  N.I.~Kalinin , V.F.~Boreyko,
  A.A.~Timoshenko, V.~Romanov, M.~Finger, B.M.~Sabirov, Nguen Man Shat}
\PL{VBLHEP}{}{N.V.~Gorbunov}
\PL{LIT}{}{S.K.~Slepnev}

\item  \PS{Experiment TUS }{L.G.~Tkatchev}{\psinp}
\PL{DLNP}{}{V.M.~Grebenyuk,  S.Yu.~Porokhovoy, A.V.~Tkachenko, F.F.~Grinyuk,
  M.~Slunechka, V.~Slunechkova, N.~ Zaikova, N.I.~Kalinin , V.F.~Boreyko,
  A.A.~Timoshenko}
\PL{VBLHEP}{}{N.V.~Gorbunov}
%\PL{LIT}{}{S.K.~Slepnev}

\item  \PS{Experiment NUCLEON}{L.G.~Tkatchev}{\psinp}
\PL{DLNP}{}{V.M.~Grebenyuk, S.Yu.~Porokhovoy, N.I.~Kalinin, V.F.~Boreyko,
 Nguen Man Shat, B.M.~Sabirov, A.B.~Sadovsky, A.V.~Tkachenko, A.A.~Timoshenko }
\PL{VBLHEP}{}{N.V.~Gorbunov}
\PL{LIT}{}{V.N.~Shigaev, S.K.~Slepnev}
\PL{FLNP}{}{A.D.~Rogov}

%\item[] \PS{Preparation of project\\ "Showers of knowledges"}{G.A. Shelkov}{ Project preparation}
%\PL{DLNP}{}{ A.V.~Guskov,  V.O.~Gromov, A.S.~Zhemchugov, N.N.~Khovansky, V.G. Kruchonok}

\end{stage}
%%\vspace*{4mm}
\begin{intcoop}
%\mtab{Belarus}{Minsk}{NC PHEP BSU}
%\mtab{}{}{IP NASB}
\mtab{Czech Republic}{Prague}{CU}
\mtab{Germany}{Zeuthen}{DESY}
\mtab{}{Munich}{MPI-P}
%\mtab{}{Berlin}{Humboldt Uni.}
\mtab{}{Hamburg}{Univ.}
\mtab{}{T\"ubingen}{Univ.}
\mtab{Japan}{Wako}{RIKEN}
\mtab{Mexico}{Puebla}{BUAP}
\mtab{Italy}{Turin}{UniTo}
\mtab{Republic of Korea}{Seoul}{EWU}
\mtab{Romania}{Bucharest}{ISS}
\mtab{Russia }{Moscow}{SINP MSU}
\mtab{}{}{NNRU "MEPhI"}
\mtab{}{}{VNIIEM Corporation}
\mtab{}{Irkutsk}{ISU}
\mtab{}{Korolev}{RSC "Energia"}
\mtab{}{St. Petersburg}{KB "Arsenal"}
\mtab{}{Moscow, Troitsk}{INR RAS}
\mtab{Ukraine}{Kiev}{NUK}
\mtab{}{Kharkov}{ISM NASU}

\end{intcoop}




\TN{02--1--1106--2011/2016}{1}{\tsprg}
{Investigations of  Compressed Baryonic Matter at the  GSI Accelerator Complex }
{ A.I.~Malakhov\\V.V.~Ivanov}
\TLD{V.P.~Ladygin}
\TC{Bulgaria, Germany, Mongolia, Poland, Romania, Russia, Slovakia, Uzbekistan, Ukraine.}

\TA
 Design and development of the superconducting dipole magnet, transition radiation and
 straw detectors for the CBM experiment at the GSI accelerator complex.  
 Study of the multiparticle dynamics in heavy ion  collisions at SIS100 and SIS300.
 Development of algorithms and software for the trigger, simulation and data analysis. 


%%\vspace*{4mm}

{\bf Expected main results in 2015:
}
\begin{itemize}
\item Detail design of individual parts of the superconducting dipole magnet for the CBM experiment.
\item Design and testing of the prototype straw detectors.
\item Development of the algorithms and software for the trigger and data analysis.  
\item Simulation of the multiparticle dynamics in heavy ion  collisions.

\end{itemize}
%%\begin{project}
%%\item \PList{CBM}{A.I.~Malakhov}{1}{2011}{2015}
%%\end{project} 


\begin{stage}
\item \PS{CBM Project\\
 Design and manufacture of the \\superconducting dipole magnet,\\ and  straw detectors.  
 Develop-\\ment of the algorithms and software\\ for trigger, simulation and\\
  data analysis}{ A.I.~Malakhov\\V.V.~Ivanov}{\psinp}
\PL{VBLHEP}{}{E.--M. Ilgenfritz, Yu.S. Anisimov, S.N. Kuznetsov,
  Yu.V.~Zanevsky, V.F.~Chepurnov, S.P.~Chernenko, O.V. Fateev, V.N.~Zryuev,
 G.A.~Cheremukhina, V.P.~Ladygin, A.K.~Kurilkin, P.K.~Kurilkin,}
 \PL{}{}{  A.P.~Ierusalimov, A.P. Zinchenko, 
 D.V.~Peshekhonov, V.N.~Pozdnyakov, P.A.~Rukoyatkin, S.V.~Razin, V.D.~Peshekhonov, G.D.~Kekelidze, 
 V.V.~Myalkovsky, S.S.~Parzhitsky, N.S.~Grigalashvili, I.V.~Boguslavsky, V.M.~Golovatyuk, V.M.~Lysan, 
   O.V.~Rogachevsky, A.V.~Shabunov, Yu.V.~Gusakov, A.V.~Bychkov}
\PL{LIT}{}{V.V. Ivanov, P.V. Zrelov, P.G. Akishin, E.P. Akishina, T.P.~Akishina, V.P.~Akishina, 
 D.S.~Golub, O.Yu. Derenovskaya, V.V. Ivanov (jr), P.I.~Kisel, A.A.~Lebedev, 
 S.A. Lebedev, G.N. Ososkov, A.M.~Raportirenko, T.P. Sapozhnikova, V. Sheinast}
\PL{DLNP}{}{V.A. Karnaukhov,  V.V. Kirakosyan, Yu.L. Vertogradova, S.P. Avdeev, W. Karch}
\PL{BLTP}{}{D. Blaschke, V.V. Burov, S.G  Bondarenko, V.D. Toneev}
\end{stage}

\begin{intcoop}
%\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{Bulgaria}{Sofia}{INRNE BAS}
\mtab{Germany}{Darmstadt}{GSI}
\mtab{ }{Dresden }{HZDR }
\mtab{ }{Frankfurt/Main }{Univ.}
%\mtab{ }{Giessen }{JLU }
\mtab{ }{Heidelberg}{Univ.}
\mtab{Mongolia}{Ulaanbaatar}{IPT MAS}
\mtab{Poland}{Warsaw}{WUT}
\mtab{Romania}{Bucharest}{IFIN-HH}
%\mtab{}{}{INCDIE ICPE-CA}
\mtab{ Russia}{Moscow}{ITEP}
\mtab{}{}{SINP MSU}
\mtab{}{Moscow, Troitsk}{INR RAS}
\mtab{ }{Protvino }{IHEP}
\mtab{ Slovakia}{Bratislava}{IP SAS}
\mtab{}{}{CU}
\mtab{Ukraine}{Kiev}{BITP NASU}           
\mtab{Uzbekistan}{Jizzakh}{JSPI}
\mtab{}{Samarkand}{SSU}
\end{intcoop}


\TN{02--1--1096--2010/2019}{1}{\tsext}
{Study of Rare Charged Kaon Decays in Experiments\\ at the CERN SPS}
{V.D.~Kekelidze\\Yu.K.~Potrebenikov}
%\TLD{}

\TC{Belarus, Belgium, Bulgaria, CERN, Czech Republic, Germany, Italy, Mexico, Romania, Russia, Slovakia, Switzerland, United Kingdom, USA.}

\TA  Realization of the NA62 Project allows to clarify CP--violation problem, to measure precisely very
 rare charged kaon decay to charged pions and two neutrinos, to carried out a search for supersymmetric
 particles and their partners with a goal to observe a physics beyond the Standard Model. In addition, 
 characteristics of rare kaon and hyperon decays will be improved. A high resolution straw--detectors of the NA62 magnetic
 spectrometer working in vacuum will be supported during experimental runs. Software for simulation, data processing and analysis will be developed.

%%\vspace*{4mm}
%%\vspace*{4mm}

{\bf Expected main results in 2015:
}
\begin{itemize}
\item Data taking by the NA62 set--up and data analysis will be carried out. 

\item Software for the simulation of magnetic spectrometer and full set--up will
 be developed; system for detector calibration and event reconstruction will be upgraded; common software of the 
 experiment will be developed.

\item Calibration, testing a nd support of the NA62 straw detectors will be carried out.
\end{itemize}

%%%\vspace*{4mm}
%%\begin{project}
%%\item \PList{NA62}{V.D.~Kekelidze\\Yu.K.~Potrebenikov}{1}{2010}{2015}
%%\end{project} 

%%%\newpage
\begin{stage}
\item \PS{Experiment NA62}{V.D.~Kekelidze\\Yu.K.~Potrebenikov}{\pstt\\ \psmod\\ \psdt}
\PL{VBLHEP}{}{D.T.~Madigozhin, S.~Gevorgyan, A.I.~Zinchenko, N.A.~Molokanova, L.N.~Glonti, I.A.~Polenkevich,
 S.N.~Shkarovsky, M.H.~Misheva, E.A.~Gudzovsky, V.P.~Falaleev, Yu.P.~Petukhov, A.A.~Belkova,
 A.N.~Shcherbakov,  V.N.~Gorbunova, }
\PL{}{}{L.A.~Slepets, S.A~Movchan, V.I.~Gursky,  E.M.~Kislov, S.V~ Khabarov, V.S.~Khabarov, M.V.~Zaytseva,
 S.V.~Kilchakovskaya, V.V.~Elsha, T.L.~Enik, N.N.~Shcherbakov, Yu.V.~Gusakov, 
  V.A.~Samsonov,  A.O.~Kolesnikov, A.N.~Sotnikov, N.I.~Azorsky}
\PL{DLNP}{}{N.A.~Kuchinsky, V.G.~Kalinnikov, N.P.~Kravchuk}


\end{stage}

\begin{intcoop}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{Belgium}{Louvain-la-Neuve}{UCL}
\mtab{Bulgaria}{Sofia}{SU}
%\mtab{}{}{INRNE BAS}
\mtab{}{Blagoevgrad}{SWU}
\mtab{}{Plovdiv}{PU}
\mtab{CERN}{Geneva}{CERN}
\mtab{Czech Republic}{Prague}{CU}
\mtab{Germany}{Mainz}{JGU}
\mtab{Italy}{Florence}{INFN}
\mtab{}{Ferrara}{INFN}
\mtab{}{Frascati}{INFN LNF}
\mtab{}{Naples}{INFN}
\mtab{}{Perugia}{INFN}
\mtab{}{Padua}{INFN}
\mtab{}{Pisa}{INFN}
\mtab{}{Rome}{INFN}
\mtab{}{}{Univ. "Tor Vergata"}
\mtab{}{Turin}{INFN}
\mtab{Mexico}{San Luis Potosi}{UASLP}
\mtab{Romania}{Bucharest}{IFIN-HH}
\mtab{Russia}{Moscow, Troitsk}{INR RAS}
\mtab{}{Protvino}{IHEP}
\mtab{Slovakia}{Bratislava}{CU}
%\mtab{Switzerland}{Bern}{Uni Bern}
\mtab{United Kingdom}{Birmingham}{Univ.}
\mtab{}{Bristol}{Univ.}
\mtab{}{Glasgow}{US}
\mtab{}{Liverpool}{Univ.}
\mtab{USA}{Boston, MA}{BU}
\mtab{}{Chicago, IL}{UChicago}
\mtab{}{Fairfax, VA }{GMU}
%\mtab{}{Evanston, IL}{NU}
\mtab{}{Menlo Park, CA }{SLAC}
\mtab{}{Merced, CA}{UC Merced}

\end{intcoop}

%%\newpage                                                 

\TN{02--0--1083--2009/2016}{1}{\tsprg}
{CMS. Compact Muon Solenoid at the LHC}
{A.V.~Zarubin }
%%\PLDDD{I.A.~Golutvin}

\TC{Armenia, Austria, Belarus, Belgium, Brazil, Bulgaria, CERN, China, Croatia, Cyprus, Czech Republic,  Estonia, Finland, France,  
 Georgia, Germany, Greece, Hungary, India, Iran, Italy, Mexico, New Zealand, Pakistan, Poland, Republic of Korea, Russia,
 Serbia, Slovakia, Spain, Switzerland, Taiwan, Turkey, Ukraine, United Kingdom, USA, Uzbekistan.}

\TA The CMS Collaboration  has constructed a general--purpose detector to
 be operational at the start--up of the Large Hadron Collider
 (LHC/CERN) to exploit its full discovery potential. Study of fundamental properties of the matter in Super High Energy
 proton--proton and nucleus--nucleaus interactions.
 
%%\vspace*{1mm}

 The major activities of JINR are focused on the following directions:<br>

 - forward calorimetry, including endcap hadron, and preshower detector;<br>

 - forward muon stations with cathode strip chambers;<br>

 - development of Physics program to test SM and BSM.

%%\vspace*{4mm}
{\bf Expected main results in 2015:
}
\begin{itemize}
\item Upgrade and technical support of the CMS detectors.

\item CMS start up shifts, data taking, and data quality monitoring.

\item Processing and analysis of experimental data, development and improvement of muon
 and jet reconstruc\-tion algorithms.

\item Development of software for GRID--based distributed system for data processing and
 analysis. Data transmission from CERN to JINR.

\end{itemize}
%%\begin{project}
%%\item \PList{CMS}{A.V.~Zarubin \\I.A.~Golutvin }{1}{2010}{2019}
%%\item \PList{Upgrade of the CMS Detector}{A.V.~Zarubin }{1}{2013}{2015}

%%\end{project} 

\begin{stage}
\item \PS{Forward calorimetry}{A.V.~Zarubin }{\psupg\\ \pspl\\ \pspg\\ \psdt}
\PL{VBLHEP}{}{S.V. Afanasiev, M.G. Gavrilenko, I.A. Golutvin, N.S.~Golova, I.N. Gorbunov, P.D. Bunin,
 A.G.~Volodko, Yu.V.~Ershov, N.I. Zamyatin, V.D. Kalagin, A.Yu.~Ka\-menev, L.G. Kobylets, 
 A.M.~Kurenkov, P.V. Moisenz, V.A. Smirnov, A.I. Malakhov, B.S.~Yuldashev}
\PL{DLNP}{}{A.~Mestvirishvili, M.~Finger, M.~Finger (Jn.), A.~Khvedelidze, M.~Slunechka, V.~Slunechkova, A.~Yanata, 
 T.~Toriashvili, Z.~Tsamalaidze}
                                    
\item \PS{Forward muon station\\ ME1/1}{V.Yu.~Karjavin}{\psupg\\ \pspl\\ \pspg\\ \psdt}
\PL{VBLHEP}{}{S.E. Vasiliev, A.O. Golunov, I.A. Golutvin, N.V. Gorbunov, Yu.V. Ershov, 
A.V. Zarubin, A.Yu. Kamenev, A.M. Ku\-renkov, A.M. Makan'kin, V.V. Perelygin, D.A.~Smolin}
\PL{LIT}{}{V.V.~Palchik, N.N.~Voytishin}

\item \PS{Upgrade of the CMS detectors}{I.A.~Golutvin}{\psinp}
\PL{VBLHEP}{}{S.V.~Afanasiev, N.V.~Gorbunov, V.Yu.~Karjavin, A.M.~Kurenkov, Yu.V.~Ershov, S.E.~Vasiliev, A.V.~Zarubin,
 A.M~ Makan'kin, A.I.~Malakhov, P.V.~Moisenz, V.V.~Perelygin, V.A.~Smirnov}
\PL{LIT}{}{V.V.~Palchik, N.N.~Voytishin}

\item \PS{Reserch physics programme\\with the CMS Detector}{S.V.~Shmatov\\I.A.~Golutvin}{\psinp}
\PL{VBLHEP}{}{S.V. Afanasiev, M.G. Gavrilenko, I.N. Gorbunov, I.M.~Gramenitsky, I.I. Belotelov,
 P.D. Bunin, A.V.~Zarubin, A.Yu. Kamenev, V.F. Konoplyanikov, L.G. Kobylets,  A.V.~Lanev, P.V. Moisenz,
 M.A.~Podoynitsin, M.V. Savina, A.I. Malakhov, S.G.~Shulga, B.S.~Yuldashev}
\PL{LIT}{}{V.V.~Korenkov, D.A. Oleynik, G.A. Ososkov, V.V. Palchik, A.Sh.~Petrosyan, N.N.~Voytishin}
\PL{BLTP}{}{G.A.~Kozlov, A.B.~Arbuzov, A.V.~Kotikov, A.V.~Sidorov, A.V.~Efremov, 
 S.G.~Bondarenko, R.S.~Pasechnik, O.V.~Teryaev}
\PL{DLNP}{}{ G.A.~Golovanov, P.X.~Khristova, M.~Finger, M.~Finger~(Jr.), N.B.~Skachkov, A.N.~Skachkova, A.Yu.~Verkheev}
%%%\newpage

\item \PS{Development of software for\\distributed computation, data
\\processing and analysis based\\on GRID--technology }{V.V.~Korenkov }{\psinp}
\PL{LIT}{}{V.V.~Mitsyn, V.V.~Palchik, R.N.~Semenov, E.A.~Tikhonenko, 
 I.A.~Filozova, N.N.~Voytishin}
\PL{VBLHEP}{}{I.I. Belotelov, I.N. Gorbunov, N.V. Gorbunov, A.O. Golunov, P.V. Moisenz, S.V.~Shmatov}
\end{stage}

\begin{intcoop}
\mtab{Armenia}{Yerevan}{YerPhI}
\mtab{Austria}{Vienna}{HEPHY}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
%\mtab{}{}{JIPNR-Sosny NASB}
\mtab{}{}{INP BSU}
\mtab{}{Gomel}{BelSUT}
\mtab{}{}{GSU}
\mtab{Belgium}{Louvain-la-Neuve}{UCL}
\mtab{}{Antwerp}{UA}
\mtab{}{Brussels}{ULB}
\mtab{}{}{VUB}
\mtab{}{Mons}{UMONS}
\mtab{Brazil}{Rio de Janeiro, RJ}{CBPF}
\mtab{}{}{UERJ}
\mtab{}{}{UFRJ}
\mtab{}{Sao Paulo, SP}{Unesp}
\mtab{Bulgaria}{Sofia}{SU}
\mtab{}{}{INRNE BAS}
\mtab{CERN }{Geneva}{CERN}
\mtab{China }{Hefei}{USTC}
\mtab{}{Beijing}{IHEP CAS}
\mtab{}{}{PKU}
\mtab{Croatia }{Split}{Univ.}
\mtab{Cyprus }{Nicosia}{UCY}
\mtab{Czech Republic}{Prague}{CU}
\mtab{Estonia }{Tallinn}{NICPB}
\mtab{Finland }{Helsinki}{UH}
%\mtab{}{}{HUT}
\mtab{}{}{HIP}
\mtab{}{Jyvaskyla}{UJ}
\mtab{}{Oulu}{UO}
\mtab{}{Tampere}{TUT}
\mtab{France }{Annecy-le-Vieux}{LAPP}
\mtab{}{Lyon}{IPNL}
\mtab{}{Saclay}{IRFU}
\mtab{}{Strasbourg}{IPHC}
\mtab{Georgia }{Tbilisi}{HEPI-TSU}
\mtab{}{}{AIP}
\mtab{Germany}{Berlin}{HUB}
\mtab{}{Aachen}{RWTH }
\mtab{}{Karlsruhe}{KIT}
\mtab{Greece }{Athens}{INP NCSR "Demokritos"}
\mtab{}{}{UoA}
\mtab{}{Ioannina}{UI}
\mtab{Hungary }{Budapest}{Wigner RCP}
\mtab{}{Debrecen}{Atomki}
\mtab{}{}{UD}
\mtab{India }{Mumbai}{BARC}
\mtab{}{}{TIFR }
\mtab{}{Bhubaneshwar}{IOP}
\mtab{}{Chandigarh}{PU}
\mtab{Iran}{Tehran}{IPM}
\mtab{Italy}{Bari}{INFN }
\mtab{}{Bologna}{INFN}
\mtab{}{Catania}{INFN LNS}
\mtab{}{Florence}{INFN}
\mtab{}{Genoa}{INFN}
\mtab{}{Padua}{ INFN}
\mtab{}{Pavia}{ INFN}
\mtab{}{Perugia}{ INFN}
\mtab{}{Pisa}{ INFN}
\mtab{}{Rome}{ INFN}
\mtab{}{Turin}{ INFN}
\mtab{Mexico}{Mexico }{Cinvestav}
\mtab{New Zealand}{Auckland}{Univ.}
\mtab{}{Christchurch}{UC}
\mtab{Pakistan}{Islamabad}{QAU}
\mtab{Poland}{Warsaw}{UW}
\mtab{}{Otwock-Swierk}{NCBJ}
\mtab{Republic of Korea}{Kwangju}{CNU}
\mtab{}{Naju}{DU}
\mtab{}{Namwon}{SU}
\mtab{}{Seoul}{KU}
\mtab{}{}{Konkuk Univ.}
\mtab{}{}{ SNUE}
\mtab{}{Chongju}{CBNU}
\mtab{Russia}{Moscow}{ITEP}
\mtab{}{}{LPI RAS}
\mtab{}{}{SINP MSU}
\mtab{}{}{NIKIET}
\mtab{}{Moscow, Troitsk}{INR RAS}
\mtab{}{Gatchina}{PNPI}
\mtab{}{Protvino}{IHEP}
\mtab{}{Snezhinsk}{VNIITF}
\mtab{}{St. Petersburg}{Electron}
\mtab{}{Zhukovsky}{MDB}
\mtab{Serbia }{Belgrade}{INS "VINCA"}
\mtab{Slovakia }{Bratislava}{STU}
\mtab{Spain }{Madrid}{CIEMAT}
\mtab{}{}{UAM}
\mtab{}{Oviedo}{Uniovi}
\mtab{}{Santander}{IFCA}
\mtab{Switzerland }{Zurich}{ETH}
\mtab{}{}{UZH}
\mtab{}{Villigen}{PSI}
\mtab{}{Basel}{Uni Basel}
\mtab{Taiwan}{Taipei}{NTU}
\mtab{}{Chung--Li}{NCU}
\mtab{Turkey}{Adana}{CU}
\mtab{}{Ankara}{METU}
\mtab{Ukraine}{Kharkov}{KFTI NASU}
\mtab{}{}{ISC NASU}
\mtab{}{}{KhNU}
\mtab{United Kingdom }{London}{Imperial College}
\mtab{}{Didcot}{RAL}
\mtab{}{Bristol}{Univ.}
\mtab{USA}{Ames, IA}{ISU}
\mtab{}{Baltimore, MD}{JHU}
\mtab{}{Batavia, IL}{Fermilab}
\mtab{}{Blacksburg, VA}{Virginia Tech.}
\mtab{}{Boston, MA}{BU}
\mtab{}{}{NU}
\mtab{}{Cambridge, MA}{MIT}
\mtab{}{Chicago, IL}{UIC}
\mtab{}{College Park, MD}{UM}
\mtab{}{Columbus, OH}{OSU}
\mtab{}{Davis, CA}{UCDavis}
\mtab{}{Gainesville, FL}{UF}
\mtab{}{Evanston, IL}{NU}
\mtab{}{Houston, TX}{Rice Univ.}
\mtab{}{Iowa City, IA}{UIowa}
\mtab{}{Lincoln, NE}{UNL}
\mtab{}{Livermore, CA}{LLNL}
\mtab{}{Los Alamos, NM}{LANL}
\mtab{}{Los Angeles, CA}{UCLA}
\mtab{}{Lubbock, TX}{TTU}
\mtab{}{Madison, WI}{UW-Madison}
\mtab{}{Minneapolis, MN}{UofM}
\mtab{}{Notre Dame, IN}{ND}
\mtab{}{Oxford, MS}{UM}
\mtab{}{Pasadena, CA}{Caltech}
\mtab{}{Pittsburgh, PA}{Pitt}
\mtab{}{Piscataway, NJ}{Rutgers}
\mtab{}{Princeton, NJ}{PU}
\mtab{}{Riverside, CA}{UCR}
\mtab{}{Rochester, NY}{UR}
\mtab{}{Tallahassee, FL}{FSU}
\mtab{ }{Tuscaloosa, AA}{UA}
\mtab{Uzbekistan}{Tashkent}{INP UAS}
\end{intcoop}

%%\newpage

\TN{02--0--1085--2009/2016}{1}{\tsprg}
{Studies of the Nucleon and Hadron Structure at  CERN }
{A.P.~Nagaytsev }
%%\PLDDD{ I.A.~Savin}

\TC{Armenia, Belarus, Bulgaria,  CERN, Czech Republic, France, Germany, Israel, Italy, Japan, 
 Poland, Russia, Switzerland, Ukraine, United Kingdom, USA.}

\TA Studies of the Primakoff reactions and diffractive proctsses. Studies of the generalized parton 
 distributions in various exclusive processes and participation in construction of new electromagnatic
 calorimeter. Studies of the exclusive production of photons, pions and vector mesons in DIS and DVCS.
 Measurements of nucleon structure in the Drell--Yan processes. Study of inclusive and semi--inclusive 
 processes in Deep Inelastic Scattering (DIS) of muons and hadrons on polarized targets. The mesurements
 of the new structure functions characterizing the transverse quark distributions in polarized nucleons.  

%%\vspace*{1mm}
\begin{itemize}
\item Measurements of the nucleon structure functions, polarized parton distributions.
\item Pion and kaon polarizabilities measurements.
\item Search of new bound states of quarks and gluons.
\item Measurements of nucleons structure in the Drell--Yan processes.
\item Studies of the inclusive production of photons, pions and $\rho$--mesons in DIS and DVCS.
\item Software creation and development for simulation and data analysis. System support of CERN software in COMPASS--II.
\item Creation of the new electromagnetic calorimeter for COMPASS--II.
\item Detector preparation for the COMPASS--II spectrometer. 

\end{itemize}


%%\vspace*{4mm}
{\bf Expected main results in 2015:
}
\begin{itemize}
\item	Measurement of the Drell-Yan process.
\item Participation in the data taking.
\item Maintenance of the hadron calorimeter HCAL1 and muon system MW1.
\item Testing, assembly and commissioning of the new electromagnetic calorimeter ECALO for COMPASS--II.
\item Software development and simulation of the various reactions, studied in COMPASS--II. Analyzing 
 of the COMPASS--II data at JINR and publications preparation.
\item Theoretical studies for COMPASS--I and COMPASS--II.

\end{itemize}

%%\begin{project}
%%\item \PList{COMPASS--II}{A.P.~Nagaytsev}{1}{2011}{2016}
%%
%%\end{project} 


\begin{stage}

\item[I.] \PS{Experiment COMPASS}{A.P.~Nagaytsev}{\psdt\\ \psda}

\item \PS{Hadron calorimeter}
    { I.A.~Savin\\O.P.~Gavrishchuk}{\pspg}
\PL{VBLHEP}{}{ G.V.~Meshcheryakov, N.N.~Vlasov, A.S.~Yukaev, V.A.~Anosov}

\item \PS{Electromagnetic calorimeter}{A.P.~Nagaytsev,\\ Z.V.~Krumshtein}{\pspp\\ \pspt}
\PL{VBLHEP}{}{O.P.~Gavrishchuk, G.V.~Meshcheryakov, A.S.~Yukaev, N.S.~Rossiyskaya, O.M.~Kuznetsov, V.A.~Anosov}
\PL{DLNP}{}{I.E.~Tchirikov--Zorin, N.V.~Anfimov, T.V.~Rezinko, I.A.~Orlov, V.V.~Tchalyshev, A.V.~Rybnikov, D.V.~Fedossev, A.S.~Selyunin, A.G.~Olshevskiy, O.V.~Gromov}

\item \PS{Muon system}{G.D.~Alekseev}{\pspg}
\PL{DLNP}{}{ N.I.~Zhuravlev, N.A.~Kutchinsky, V.L.~Malyshev}

\item \PS{Software development.\\ Data analysis}{ E.V.~Zemlyanichkina}{\psinp}
\PL{VBLHEP}{}{I.A.~Savin, D.V.~Peshekhonov, 
 G.I.~Smirnov, A.P.~Nagaytsev, O.M.~Kuznetsov, Yu.I.~Ivanshin, 
  N.S.~Rossijskaya, R.R.~Akhunzyanov, R.~Gushcherski, A.V.~Ivanov, V.S.~Batozskaya, E.A.~Salmina}
\PL{DLNP}{}{A.G.~Olshevskiy, A.V.~Guskov, Z.V.~Krumshtein, K.Yu.~Gasnikova, I.A.~Orlov, N.V.~Anfimov, T.V.~Rezinko, A.V.~Rybnikov, A.S.~Selyunin}
\PL{LIT}{}{P.V.~Zrelov} 

\item \PS{ Measurements of generalized\\ parton distributions and\\ transverse spin structure\\
 in Drell--Yan processes. Development of new electro-magnetic\\ calorimeter}{A.P.~Nagaytsev\\I.A.~Savin}{\psinp} 
\PL{VBLHEP}{}{ O.P.~Gavrishchuk, G.V~Meshcheryakov, O.M.~Kuznetsov, Yu.I.~Ivanshin, R.R.~Akhuzyanov, N.S.~Rossijskaya, E.V.~Zemlyanichkina, A.V.~Ivanov}
\PL{DLNP}{}{A.G.~Olshevskiy, Z.V. Krumshtein, A.V. Guskov, K.Yu.~Gasnikova, I.A.~Orlov, N.V.~Anfimov, T.V.~Rezinko, A.V.~Rybnikov, A.S.~Selyunin}
\PL{BLTP}{}{A.V.~Efremov, O.V.~Teryaev}

\item \PS{Preparation of the project\\ on measurement of proton form--factor ratios\\
 at 13--15~GeV/c}{I.A.~Savin\\N.M.~Piskunov}{Project preparation}
\PL{VBLHEP}{}{O.P.~Gavrishchuk, G.V.~Meshcheryakov}

\item[II.] \PS{Theoretical studies}{ A.V.~Efremov}{\psinp}
\PL{BLTP}{}{S.B.~Gerasimov, O.V.~Teryaev, A.V.~Kotikov, A.E.~Dorokhov, N.I.~Kochelev, A.M.~Sidorov}

\end{stage}

\begin{intcoop}
\mtab{Armenia }{Yerevan}{YerPhI}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{}{}{JIPNR-Sosny NASB}
\mtab{Bulgaria}{Sofia}{INRNE BAS}
\mtab{}{}{SU}
%\mtab{Canada}{Vancouver}{TRIUMF}
%\mtab{}{Edmonton}{U of A}
\mtab{CERN}{Geneva}{CERN}
\mtab{Czech Republic}{Prague}{CTU}
\mtab{France}{Saclay}{IRFU}
\mtab{Germany}{Bielefeld}{Univ.}
\mtab{}{Bochum}{RUB}
\mtab{}{Bonn}{UniBonn}
\mtab{}{Freiburg}{Univ.}
\mtab{}{Hamburg}{DESY}
\mtab{}{Heidelberg}{MPIK}
\mtab{}{Munich}{LMU}
\mtab{}{}{TUM}
\mtab{}{Mainz}{JGU}
\mtab{}{Erlangen}{FAU}
\mtab{Israel}{Tel Aviv}{TAU}
\mtab{Italy}{Turin}{INFN}
\mtab{}{Trieste}{INFN}
\mtab{}{Frascati}{INFN LNF}
\mtab{Japan}{Chiba}{Toho Univ.}
\mtab{}{Nagoya}{Nagoya Univ.}
\mtab{}{Osaka}{OCU}
\mtab{}{Sendai}{Tohoku Univ.}
\mtab{}{Tsukuba}{KEK}
\mtab{}{Yamagata}{Yamagata Univ.}
%\mtab{Netherlands}{Amsterdam}{ NIKHEF}
\mtab{Poland}{Warsaw}{WUT}
\mtab{Russia}{Moscow}{SINP MSU}
\mtab{}{}{LPI RAS}
\mtab{}{Moscow, Troitsk}{INR RAS}
\mtab{}{Gatchina}{PNPI}
\mtab{}{Protvino}{IHEP}
\mtab{Switzerland}{Zurich}{UZH}
\mtab{Ukraine}{Kharkov}{ISM NASU}
\mtab{United Kingdom}{Liverpool}{Univ.}
\mtab{USA}{Urbana, IL}{UIUC}
%\mtab{}{Boulder, WY}{CU}
%\mtab{}{Cambridge, MA}{MIT}
%\mtab{}{Pasadena, CA}{Caltech}

\end{intcoop}

%%\newpage


\TN{02--1--1086--2009/2017}{1}{\tsext}
{Strangeness in Hadronic Matter and Study of Inelastic Reactions Near Kinematical Borders}
{E.A.~Strokovsky\\E.S.~Kokoulina}

\TC{Belarus, Czech Republic, Germany, Japan, Russia, Ukraine.} 

\TA Strangeness in hadronic matter and study of boundary effects:
\\  study of stabilizing effects of strangeness in nuclear matter and properties of the
 lightest hypernuclei;
\\ study of multi--particle dynamics in inelastic proton--proton and proton--nucleus interactions
 with extremally high multiplicity;
\\ study of spectra and yields of soft photons in deuteron--nucleus and nucleus--nucleus interactions.
%%\vspace*{2mm}

{\bf Expected results:
}
\begin{itemize}

\item	Data on production cross sections for hyper--fragments of relativistic nuclei.
 Data on the lifetimes and binding energies of the lightest hypernuclei
 $^4_{\Lambda}{H},\:^3_{\Lambda}{H},\:^6_{\Lambda}{H}$; search for $^6_{\Lambda}{H}$.
 Study of the decay channels, including non--mesonic decays of the
 $^{10}_{\Lambda}{Be}$ and $^{10}_{\Lambda}{B}$ hypernuclei.

\item New experimental data about the drip--line location for loosly bound light hypernuclei with high neutron excess.
 Development of theory of the neutron--rich hyper nuclei and models of their production in non--central nucleus--nucleus interactions.

\item	New experimental data about soft photon emission in deuteron--nuclei and nuclei--nuclei interactions, including
 study of dependence of their energy spectra on electric charges of the projectile and target nuclei, as well as on multiplicity of secondaries.

\item	Development of theoretical and phenomenological models for description of data on the soft photon yields in tne 
 non--central deuteron--nuclei and nuclei--nuclei iteractions, differentiated on multiplicity of secondaries.

\item	Construction of two--arm electromagnetic calorimeter for soft photon registration in a wide region of emission angles
 for study of interference patterns aimed on search of new resonances and verification of theoretical predictions about
  new phenomena in a dense nuclear matter.
\end{itemize}

%%\vspace*{4mm}

{\bf Expected main results in 2015:}
\begin{itemize}

\item Modernization of the FFE, DAQ and tracking systems of the NIS--GIBS spectrometer. 

\item Data taking on the hyper--nuclear program (search for the hyper--hydrogen 6) using the NIS--GIBS
 spectrometer at extracted beams of deuterons and $^{7}{Li}$ nuclei.

\item Analysis of data from LEPS spectormeter on vector--meson photoproduction by polarized photons.

\item	Analysis of data on soft ($E_{\gamma}$ < 50 MeV) photon emission in deuteron--nuclei and nuclei--nuclei
 interactions at kinetic energies above 2 GeV/nucleon.

\item	Preparation of the NEMAN project aimed on study of photon emission in non--central collisions of relativistic
 (with kinetic energies above 1 GeV/nucleon) heavy nuclei with nuclei at the BM@N setup.

\end{itemize}

%%\vspace*{4mm}

%%\begin{project}
%%\item \PList{HyperNIS}{E.A.~Strokovsky}{1}{2010}{2015}
%%%\item \PList{THERMALIZATION}{E.S.~Kokoulina}{2}{2003}{2011}
%%\end{project} 

\begin{stage}
\item \PS{Experiment NIS--GIBS}{E.A.~Strokovsky\\J.~Lukstins}{\psinp\\ \psdt}
\PL{VBLHEP}{}{V.D.~Aksinenko, R.A.~Salmin, V.P.~Balandin, S.N.~Bazylev, 
 P.A.~Rukoyatkin, A.A.~Feschenko, S.N.~Plyashkevich, J.~Lukstins,
 Yu.T.~Borzunov, V.D.~Aksinenko, A.I.~Maksimchuk, V.B.~Chumakov, V.Yu.~Ivanenko,
 O.V.~Okhrimenko, A.I.~Golokhvastov, S.A.~Avramenko, M.H.~Anikina, A.V.~Averiyanov, A.M.~Korotkova, N.G.~Parfenova, S.V.~Starikova,
 V.B.~Dunin + 2 students, A.V.~Konstantinov}
\PL{DLNP}{}{ V.~Tereschenko, Yu.A.~Batusov}
\PL{OCE}{}{A.N.~Parfenov}

\item \PS{Experiment NEMAN}{E.S.~Kokoulina\\V.A.~Nikitin}{\pspd\\ \psdt}
\PL{VBLHEP}{}{V.I.~Kireev, V.V.~Avdeychikov, Yu.A.~Chentsov,  I.A.~Rufanov, V.A.~Nikitin,
 M.V.~Tokarev, Yu.P.~Petukhov, A.N.~Aleev, A.I.~Yukaev, N.K.~Zhidkov, V.V.~Pavlyuchkov, V.B.~Dunin + 3 students,  V.P.~Balandin, N.F.~Furmanets}
\PL{BLTP}{}{Yu.A.~Bystritsky}
\end{stage}

%%\vspace*{8mm}
\begin{intcoop}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{}{}{BSUIR}
\mtab{}{Gomel}{GSTU}
\mtab{}{}{GSU}
\mtab{Czech Republic}{Prague}{CTU}
\mtab{}{Rez}{NRI}
\mtab{}{}{NPI ASCR}
\mtab{Germany}{Frankfurt/Main}{Univ.}
%\mtab{}{Munich}{LMU}
\mtab{}{Julich}{FZJ}
%\mtab{Italy}{Kosenza}{UniCal}
\mtab{Japan}{Osaka}{RCNP}
\mtab{Russia}{Moscow}{SINP MSU}
\mtab{}{Protvino}{IHEP}
\mtab{}{Syktyvkar}{DM Komi SC UrD RAS}
\mtab{Ukraine}{Kiev}{BITP NASU}

\end{intcoop}


\TN{02--1--1093--2009/2015}{1}{\tscom}
{ Development of High-Precision Straw Detectors}
 {V.D.~Peshekhonov }

\TC{Belarus, Bulgaria, Germany, Georgia, Russia.} 

\TA Investigation and development of tracking straw detectors with different pressure
 of its gas mixture for applica\-tion in high luminosity accelerator experiments and for
 application in other fields.

%%\vspace*{4mm}

{\bf Expected main results in 2015:
}
\begin{itemize}
\item Preparing documentation on the coordinate detector modules with a sensitive area of 
$\sim$14~m$^2$~sq based on the results of the engineering prototype studies.

\item Creation of the detector prototype with the cathode registration readout and preparation to bench and beam tests.

\item Study possibility the detect of the pairs events with small distances between them. 

\item Development of the fast analog electronics for the straw detectors.

\item Development and production of the tipical elements for the straw detectors and the assembly tools.
\end{itemize}

\begin{stage}
\item[] \PS{STRAW Detectors}
{V.D.~Peshekhonov}{\psinp}
\PL{VBLHEP}{}{A.E.~Baskakov, S.N.~Bazylev, E.V.~Vasilieva, I.V.~Boguslavsky, N.~Grigalashvili, 
G.D.~Kekelidze, V.M~ Lysan, V.V.~Myalkovsky, G.S.~Berezin, S.V.~Rabtsun, V.~Cholakov }
\end{stage}

\begin{intcoop}
\mtab{Belarus}{Minsk}{NC PHEP BSU}
\mtab{Bulgaria}{Plovdiv}{PU}
\mtab{Georgia}{Tbilisi}{TSU}
\mtab{Germany}{Darmstadt}{GSI}
%\mtab{Poland}{Warsaw}{WUT}
\mtab{Russia}{Moscow}{SINP MSU}
\mtab{}{}{LPI RAS}
\mtab{}{Moscow, Troitsk}{INR RAS}
\mtab{}{Protvino}{IHEP}
\end{intcoop}