tipp2014

tipp2014@nikhef.nl

1261 discussions

[Tipp2014] [Indico] New abstract submission: TONELLI, Diego
by noreply-indico-team＠cern.ch 27 Jan '14

27 Jan '14

The following email has been sent to TONELLI, Diego: === Dear Diego Tonelli, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=39&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: TONELLI, Diego Submitted on: 27 January 2014 09:25 Title: A specialized processor for track reconstruction at the LHC crossing rate Abstract content We present the results of an R\&D study for a specialized processor capable of precisely reconstructing events with hundreds of charged-particle tracks in pixel detectors at 40 MHz, thus suitable for processing LHC events at the full crossing frequency. For this purpose we design and test a massively parallel pattern-recognition algorithm, inspired by studies of the processing of visual images by the brain as it happens in nature. We find that high-quality tracking in large detectors is possible with sub-microsecond latencies if the algorithm is implemented in modern, high-speed, high-bandwidth FPGA devices. Summary Primary Authors: TONELLI, Diego (CERN) <diego.tonelli(a)cern.ch> Co-authors: Abstract presenters: TONELLI, Diego Track classification: Data-processing: 3b) Trigger and Data Acquisition Systems Presentation type: --not specified-- Comments:

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[Tipp2014] [Indico] New abstract submission:
by noreply-indico-team＠cern.ch 27 Jan '14

27 Jan '14

The following email has been sent to : === Dear , The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=38&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: Submitted on: 27 January 2014 07:45 Title: Measurement of characteristics of MICROMEGAS gaseous detectors on Synchrotron Radiation Abstract content With the continuous development of the micro-structure of gaseous detectors in recent years, a lot of the new detection requirements have been proposed in synchrotron radiation facility. To get the stable working time, lower discharge rate with long working term and higher effective gain, the new structure detector has been designed. One structure was based the coated Ge resistive anode readout with bulk Micromegas detector, and the other structure was combined with the detection’s advantages of Micromegas and gas electron multiplier (GEM), which was composed of a Micromagas chamber with one GEM foil as preamplifier. In this paper, the two structures of the detectors and detection principles were presented in details. Using a 55Fe X-ray radioactive source in the operation mixtures gas of argon and isobutene (Ar/Iso=95/5), the performances of the detector gain, discharge rate, energy resolution and stable working time are investigated. A further measurement in the four operation mixtures gas has been accomplished at 1W1B laboratory of Beijing Synchrotron Radiation Source. In the experiment, the energy range of X-ray was set from 6 keV to 20 keV and the setting step was 1 keV. Finally, the data of beam test were obtained and analyzed. The preliminary results show that a stable working time could reach more than 30 hours of continuous work, the gain of the detector could exceed 10^6 and the discharge rate could be reduced by nearly 100 times at the same gain. Summary Primary Authors: Dr. QI, Huirong (IHEP,CAS) <qihr(a)ihep.ac.cn> Co-authors: Abstract presenters: Dr. QI, Huirong Track classification: Sensors: 1c) Gaseous Detectors Presentation type: --not specified-- Comments:

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[Tipp2014] [Indico] New abstract submission: BURNS, Jonathan
by noreply-indico-team＠cern.ch 25 Jan '14

25 Jan '14

The following email has been sent to BURNS, Jonathan: === Dear Jonathan Burns, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=37&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: BURNS, Jonathan Submitted on: 25 January 2014 19:03 Title: Muon Scattering Tomography using Drift Chamber Detectors Abstract content Muon scattering tomography (MST) allows the identification of shielded high atomic number, or Z materials by measuring the scattering angle of atmospheric cosmic ray muons passing through an inspection region. Materials of different densities can be differentiated using this technique as muons interacting with high-Z materials are scattered to a greater degree by multiple Coulomb scattering than low-Z materials. This scattering is determined experimentally by detecting the incoming and outgoing trajectory of the muon as it enters and exits the inspection volume. This technique is particularly useful for visualising volumes that are difficult to inspect visually. AWE is primarily interested in investigating the use of MST for scanning cargo containers, as it could be used for the detection the presence of radiological material without introducing an artificial radiation source. AWE is currently testing and developing two MST experimental systems based on drift chamber technology. One of the experiments is constructed using six layers of three adjacent drift chambers positioned above and below an inspection volume. The second system is a similar configuration and is constructed of drift tubes. The technical challenges of producing the experimental system with a resolution capable of accurately determining the muon scattering angle within a few milliradians will be detailed and the experimental results obtained compared with Monte Carlo models. Summary Primary Authors: Dr. BURNS, Jonathan (AWE) <jon.burns(a)awe.co.uk> Co-authors: Dr. STEER, Christopher (AWE) <chris.steer(a)awe.co.uk> Mr. QUILLIN, Stephen (AWE) <steve.quillan(a)awe.co.uk> Dr. STAPLETON, Matthew (AWE) <matt.stapleton(a)awe.co.uk> Abstract presenters: Dr. BURNS, Jonathan Track classification: Sensors: 1c) Gaseous Detectors Presentation type: --not specified-- Comments:

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Re: [Tipp2014] TIPP2014 - Abstract submission open
by Kajari Mazumdar 25 Jan '14

25 Jan '14

Dear Organizers, This is on behalf of the Conference committee of CMS collaboration at LHC. CMS is interested in submitting many abstracts for the conference, and I have 2 questions regarding this as the coordinator within the conference committee. 1. In Indico, shall I submit all the abstracts with myself as the presenter? 2. Not in all cases the tracks can be specified exclusively. Or several abstracts may fall into multiple categories. Could you kindly help me? Kind regards -- Kajari Mazumdar On Thu, Jan 23, 2014 at 7:34 PM, Joan Berger <jberger(a)nikhef.nl> wrote: > Dear Colleagues, > > We are pleased to announce TIPP2014, the third conference in the new > series of international conferences on detectors and instrumentation under > the auspices of IUPAP. The conference will focus on all areas of detector > development and instrumentation in particle physics, astro-particle physics > and closely related fields, and will be held in Amsterdam from June 2 - 6, > 2014. > > The conference registration and abstract submission are now open and we > invite you to submit abstracts for presentations and posters. The deadline > for abstract submission is January 31, 2014. You can find more information > about the conference in the attached 1st bulletin, or on the conference > website www.tipp2014.nl. Do not hesitate to contact us for any question > via tipp2014(a)nikhef.nl > > Please feel free to circulate this information to colleagues and persons > who could be interested in participating. > We hope to welcome you in Amsterdam! > > Niels van Bakel > for the Local Organizing Committee > > -- > Secretariaat Nikhef > Science Park 105 (v/h Kruislaan 409), 1098 XG Amsterdam > Postbus 41882, 1009 DB Amsterdam > T 0031 - 20 - 592 5169 > F 0031 - 20 - 592 5054 > E jberger(a)nikhef.nl > (aanwezig di t/m do) > >

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[Tipp2014] [Indico] New abstract submission: BRENNER, Richard
by noreply-indico-team＠cern.ch 24 Jan '14

24 Jan '14

The following email has been sent to BRENNER, Richard: === Dear Richard Brenner, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=36&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: BRENNER, Richard Submitted on: 24 January 2014 14:40 Title: Wireless data transfer with mm-waves for future tracking detectors Abstract content Wireless data transfer has revolutionized the consumer market for the last decade giving products equipped with transmitters and receiver for wireless data transfer. Wireless technology has features attractive for data transfer in future tracking detectors. The removal of wires and connectors for data links is certainly beneficial both for the material budget and the reliability of the system. Other advantages is the freedom of routing signals which today is particularly complicated when bringing the data the first 50 cm outside the tracker. With wireless links intelligence can be built into a tracker by introducing communication between tracking layers within a Region Of Interest which would allow the construction of track primitives in real time. The wireless signal is transmitted by a passive antenna structure which is clearly a much less complex and radiation hard object than an optical transmitter. The technology used in consumer goods are however not suitable for trackers. The first limitation is the low data transfer capacity with current 5 GHz transceivers but also the relatively large feature sizes of the components. Due to the requirement of high data rates in detectors a high bandwidth is required. The frequency band around 60 GHz turns out to be a very promising candidate. The frequency is a strong candidate for future WLAN use hence components are available on the market. The high baseband frequency allow for data transfer of the order of several Gbit , and due to the small wave length in the mm range, only small structures are needed. The challenge is to bring the signal around or trough boundaries that are not transparent to the mm-waves like silicon detector modules or support structure. Further more low power operation and strong focusing antennas is required for massive parallelization of data transfer inside the tracker. We will present patch antennas produced on flexible Printed Circuit Board substrate that can be used in future trackers. The antennas can be connected to transceivers for data transmission/reception or be connected by wave-guides to structures capable of bringing the signal pass boundaries. This presentation aims to present results on simulation, modelling, fabrication and characterisation of such antennas. Studies of a 60 GHz data link for radial transmission of mm-waves through a ATLAS detector model will be shown. Summary Primary Authors: BRENNER, Richard (Uppsala University (SE)) <richard.brenner(a)cern.ch> PELIKAN, Daniel (Uppsala University (SE)) <daniel.pelikan(a)cern.ch> Co-authors: Dr. DANCILA, Dragos (Uppsala University) <dragos.dancila(a)angstrom.uu.se> GUSTAFSSON, Leif (Uppsala University) <leif.gustafsson(a)physics.uu.se> Mr. BINGEFORS, Nils (Uppsala University) <nilsb(a)tsl.uu.se> Abstract presenters: PELIKAN, Daniel Track classification: Experiments: 2a) Experiments & Upgrades Data-processing: 3b) Trigger and Data Acquisition Systems Presentation type: --not specified-- Comments:

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[Tipp2014] [Indico] New abstract submission: PERRET, Pascal
by noreply-indico-team＠cern.ch 24 Jan '14

24 Jan '14

The following email has been sent to PERRET, Pascal: === Dear Pascal Perret, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=35&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: PERRET, Pascal Submitted on: 24 January 2014 13:54 Title: First years of running for the LHCb calorimeter system Abstract content The LHCb experiment is dedicated to precision measurements of CP violation and rare decays of B hadrons at the Large Hadron Collider (LHC) at CERN (Geneva). It comprises a calorimeter system composed of four subdetectors: an electromagnetic calorimeter (ECAL) followed by a hadron calorimeter (HCAL). In addition the system includes in front of them the Scintillating Pad Detector (SPD) and Pre-Shower (PS). They are used to select transverse energy hadron, electron and photon candidates for the first trigger level and they provides the identification of electrons, photons and hadrons as well as the measurement of their energies and positions. The calorimeter has been pre-calibrated before its installation in the pit, and the calibration techniques have been tested with the data taken in 2010. During operation, hadronic, leptonic and photon triggers of particular interest for hadronic B decays and radiative decays are provided by the calorimeter system. The design and construction characteristics of the LHCb calorimeter will be recalled. Strategies for monitoring and calibration during data taking will be detailed in all aspects. Scintillating fibres, plastics and photomultipliers suffer from ageing due to radiation damage or high currents. Different methods which are used to calibrate the detectors and to recover the initial performances will be presented. The performances achieved will be illustrated in selected channels of interest for B physics. Summary The LHCb experiment is dedicated to precision measurements of CP violation and rare decays of B hadrons at the Large Hadron Collider (LHC) at CERN (Geneva) [1, 2]. LHCb is a single-arm spectrometer with a forward angular coverage from approximately 10 mrad to 300 mrad. It comprises a calorimeter system composed of four subdetectors [3], selecting transverse energy hadron, electron and photon candidates for the first trigger level (L0), which makes a decision 4µs after the interaction. It provides the identification of electrons, photons and hadrons as well as the measurement of their energies and positions. The set of constraints resulting from these functionalities defines the general structure and the main characteristics of the calorimeter system and its associated electronics. A classical structure of an electromagnetic calorimeter (ECAL) followed by a hadron calorimeter (HCAL) has been adopted. In addition the system includes in front of them the Scintillating Pad Detector (SPD) and Pre-Shower (PS), which are two planes of scintillating pads separated by a 2.5 radiation length lead sheet, aimed at tagging the electric charge and the electromagnetic nature of the calorimeter clusters for the first level of trigger. ECAL, PS and SPD account for about 6000 channels each with three degrees of granularity, concentric around the beam pipe, namely, the inner, the middle and the outer parts. HCAL is made of about 1500 channels and is divided into two parts only. All four detectors are arranged in pseudo-projective geometry and follow the general principle of reading the light from scintillator tiles with wave-length shifting fibers, and transporting the light towards photomultipliers, all following the 25 ns readout. During operation, hadronic, leptonic and photon triggers of particular interest for hadronic B decays and radiative decays were provided by the calorimeter system. The calorimeter has been pre-calibrated before its installation in the pit, and each part of the calorimeter system follows a different strategy for calibration. The calibration techniques have been tested with the data taken in 2010 and have evolved to improve performances taking benefit of the high statistics recorded. Detector ageing are scrutinized regularly. They affect detector response and trigger rates but the severity of the impact on data depends on the detector type and of its use. Calibration techniques are also used to compensate for these effects. For instance ECAL aging effects can be seen from the variation on the 0 mass peak fit and the 0 peak resolution fits for calibration over time (figure 1). Regularly, a precise calibration is derived from a large sample of 0 from two separated photons. Short term effects are followed with electrons from conversion looking at the ratio of the deposited energy of the electron in the calorimeter to its momentum measured by the tracking system (E/p) in ranges of ~40 pb-1. Initial performances of the electromagnetic calorimeter and its expected resolution are recovered for 0 and B decays including photons. The design and construction characteristics of the LHCb calorimeter will be recalled. Strategies for monitoring and calibration during data taking will be detailed in all aspects. Scintillating fibres, plastics and photomultipliers suffer from ageing due to radiation damage or high currents. Different methods which are used to calibrate the detectors and to recover the initial performances will be presented. The performances achieved will be illustrated in selected channels of interest for B physics. References: [1] LHCb Collaboration, The LHCb Detector at the LHC, JINST 3 S08005 (2008), and references therein. [2] LHCb collaboration, A large Hadron Collider Beauty experiment, Technical Proposal, CERN/LHCC 1998-004. [3] LHCb Collaboration, LHCb calorimeters Technical Design Report, Technical Design Report, CERN/LHCC 2000-036. Primary Authors: PERRET, Pascal (Univ. Blaise Pascal Clermont-Fe. II (FR)) <pascal.perret(a)cern.ch> Co-authors: Abstract presenters: PERRET, Pascal Track classification: Experiments: 2a) Experiments & Upgrades Presentation type: --not specified-- Comments: This abstract is submit on behalf the LHCb collaboration. The final name of the presenter will be given later. Pascal Perret LHCb Calorimeter Project Leader

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[Tipp2014] [Indico] New abstract submission: SFORZA, Federico
by noreply-indico-team＠cern.ch 24 Jan '14

24 Jan '14

The following email has been sent to SFORZA, Federico: === Dear Federico Sforza, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=34&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: SFORZA, Federico Submitted on: 24 January 2014 11:28 Title: Upgrade of the ATLAS muon spectrometer with the installation of new precision drift-tube chambers in 2014 Abstract content We present the 2014 upgrade of a section of the muon tracker with drift-tube chambers characterized by a new technology, with smaller tube diameter than the present Monitored Drift-Tube (MDT) chambers. Each new chamber is composed by eight layers of aluminum tubes with a diameter of 15 mm, against to the six layers of 30 mm aluminum tubes used in the corresponding ATLAS MDT chambers. The newly installed chambers allow a simple integration with the services systems, electronic and muon reconstruction software. Furthermore the compact geometry of the chambers allows the installation in problematic regions of the detector structure which are, at present, instrumented with only two MDT stations instead that three as in the optimal case. The new chambers will be installed in the elevator pit area used for access to the ATLAS detector. The instrumentation of this region is possible using a movable detector structure with alignment precise at the level of 30~$\mu m$ and integrated with the rest of the ATLAS muon spectrometer. The momentum resolution for 1~TeV muons will be improved by approximately $30$\% in the newly instrumented detector regions. Summary The 2013-2014 shutdown of the Large Hadron Collider (LHC) at CERN offers the opportunity to improve the performance of the ATLAS detector with the installation of new detector components. However the relatively short time window and the constraints due to the integration of the new components with the existing infrastructure limits the range of available solutions. We present the upgrade of a section of the ATLAS muon tracker with drift-tube chambers characterized by a new technology, with smaller tube diameter than the present Monitored Drift-Tube (MDT) chambers. The proposed layout balances between maximizing the coverage with muon stations, the tight constraints of the integration with the present infrastructure, and the benefits of using the new stations for detector R\&D. Each new chamber is composed by eight layers of 78 aluminum tubes with a diameter of 15 mm, against to the six layers of 30 mm aluminum tubes used in the corresponding ATLAS MDT chambers. A gold-plated tungsten-rhenium anode wire is tensed at the center of the tubes and its position is known to better than 10~$\mu$m. The design remains fully compatible with the present services, read-out and trigger scheme but the more compact geometry of the chambers allows their installation in problematic regions of the detector structure. The presence of additional tube layers allows for redundancy in the track reconstruction and better noise rejection in the dense tracking environments expected in the future LHC run conditions. Two new chambers will be installed in the ATLAS detector elevator shaft. This region, covering an area of $\Delta \eta \times\Delta\phi\approx 0.2\times 0.3$ and corresponding to 2\% of the ATLAS barrel region, is used to access the inner part of the ATLAS detector and the ease of accessibility must be maintained. This additional challenge has been solved by installing the stations on movable supports and using an optical alignment system, precise at the level of 30~$\mu m$, integrated with the rest of the ATLAS muon spectrometer. The upgrade will increase the area of the muon spectrometer instrumented with three layers of precision tracking chambers. This will improving the momentum resolution, for 1~TeV muons, by approximately $30$\%. The newly installed chambers will also allow for test of the small drift-tube technology during the LHC Run II data taking, starting in 2015, so to prepare for the additional upgrades that will use this technology, planned for the ATLAS phase II. Primary Authors: KORTNER, Oliver (Max-Planck-Institut fuer Physik (Werner-Heisenberg-Institut) (D) <okortner(a)cern.ch> KROHA, Hubert (Max-Planck-Institut fuer Physik (Werner-Heisenberg-Institut) (D) <kroha(a)mppmu.mpg.de> RICHTER, Robert (Max-Planck-Institut fuer Physik (Werner-Heisenberg-Institut) (D) <robert.richter(a)cern.ch> SCHWEGLER, Philipp (Max-Planck-Institut fuer Physik (Werner-Heisenberg-Institut) (D) <philipp.schwegler(a)cern.ch> SFORZA, Federico (Max-Planck-Institut fuer Physik (Werner-Heisenberg-Institut) (D) <federico.sforza(a)cern.ch> Co-authors: Abstract presenters: SFORZA, Federico Track classification: Sensors: 1c) Gaseous Detectors Experiments: 2a) Experiments & Upgrades Presentation type: --not specified-- Comments:

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[Tipp2014] [Indico] New abstract submission: MATTIG, Stefan
by noreply-indico-team＠cern.ch 24 Jan '14

24 Jan '14

The following email has been sent to MATTIG, Stefan: === Dear Stefan Mattig, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=33&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: MATTIG, Stefan Submitted on: 24 January 2014 09:46 Title: Status of the CMS Phase 1 Pixel Upgrade Abstract content The silicon pixel detector is the innermost component of the CMS tracking system, providing high precision space point measurements of charged particle trajectories. Before 2018 the instantaneous luminosity of the LHC is expected to reach 2x1034cm−2s−1, which will significantly increase the number of interactions per bunch crossing. The current pixel detector of CMS was not designed to work efficiently in such a high occupancy environment and will be degraded by substantial data-loss introduced by buffering in the analogue readout chip (ROC) and effects of radiation damage in the sensors, built up over the operational period. To maintain a high tracking efficiency, CMS has planned to replace the current pixel system during „Phase 1” (2016/17) by a new lightweight detector, equipped with an additional 4th layer in the barrel, and one additional forward/backward disk. A new digital ROC has been designed, with increased buffers to minimize data-loss, and a digital readout protocol to increase the readout speed. Prototypes of digital single-chip modules have been characterized in an electron test beam at DESY, before and after irradiation. Even after the expected 4th layer lifetime dose of 130kGy, the prototypes were measured to be ~99% efficient and the spacial resolution remained ~7μm. Furthermore, energy calibrations using monochromatic X-rays were performed, and its dependence on irradiation and temperature were studied. This talk will give an overview of the upgraded detector with an emphasis on the status of the module production and testing of the 4th layer, which is being assembled and pretested by German institutes. Summary This talk will give an overview of the CMX pixel "Phase 1" upgrade with an emphasis on the status of the module production and testing of the 4th layer. Primary Authors: Dr. MATTIG, Stefan (Hamburg University (DE)) <stefan.maettig(a)cern.ch> Co-authors: Abstract presenters: Dr. MATTIG, Stefan Track classification: Sensors: 1b) Semiconductor Detectors Presentation type: --not specified-- Comments: on behalf of the CMS Tracker Collaboration

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[Tipp2014] [Indico] New abstract submission: PETRUKHIN, Alexey
by noreply-indico-team＠cern.ch 24 Jan '14

24 Jan '14

The following email has been sent to PETRUKHIN, Alexey: === Dear Alexey Petrukhin, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=32&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: PETRUKHIN, Alexey Submitted on: 24 January 2014 07:46 Title: Energy measurement with the SDHCAL prototype Abstract content The SDHCAL prototype that was completed in 2012 was exposed to beams of pions, electrons of different energies at the SPS of CERN for a total time period of 5 weeks. The data are being analyzed within the CALICE collaboration. However preliminary results indicate that a highly granular hadronic calorimeter conceived for PFA application is also a powerful tool to separate pions from electrons. The SDHCAL provides also a very good resolution of hadronic showers energy measurement. The use of multi-threshold readout mode shows a clear improvement of the resolution at energies exceeding 30 GeV with respect to the binary readout mode. New ideas to improve on the energy resolution using the topology of hadronic showers will be presented. Summary Primary Authors: Dr. PETRUKHIN, Alexey (IPNL/CNRS) <alexey.petrukhin(a)gmail.com> Co-authors: Abstract presenters: Dr. PETRUKHIN, Alexey Track classification: Sensors: 1a) Calorimetry Presentation type: --not specified-- Comments:

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[Tipp2014] [Indico] New abstract submission: Mr. CHUNDURU, Amareshwar Prasad
by noreply-indico-team＠cern.ch 23 Jan '14

23 Jan '14

The following email has been sent to Mr. CHUNDURU, Amareshwar Prasad: === Dear Amareshwar Prasad Chunduru, The submission of your abstract has been successfully processed. Abstract submitted: <https://indico.cern.ch/userAbstracts.py?confId=192695>. Status of your abstract: <https://indico.cern.ch/abstractDisplay.py?abstractId=31&confId=192695>. See below a detailed summary of your submitted abstract: Conference: Tipp 2014 - Third International Conference on Technology and Instrumentation in Particle Physics Submitted by: Mr. CHUNDURU, Amareshwar Prasad Submitted on: 23 January 2014 21:46 Title: Thermal Neutron Accelerator Abstract content The main aim of this proposal it to reveal the secrets of the universe by accelerating neutrons. The proposal idea in its abridged version speaks about the possibility of making neutrons accelerate with help of thermal energy and magnetic energy under controlled conditions. Which is helpful in revealing the hidden secrets of the universe like dark energy and in finding Higgs Boson. Summary Primary Authors: Mr. CHUNDURU, Amareswara Prasad (Undergraduate) <amarscorner(a)gmail.com> Co-authors: Abstract presenters: Mr. CHUNDURU, Amareswara Prasad Track classification: Experiments: 2b) Astrophysics and Space Instrumentation Experiments: 2c) Detectors for neutrino physics Presentation type: --not specified-- Comments:

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