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June 20-24, 2005
Bankoku Shinryoukan
Kise Nago, Okinawa
Japan
Bankoku Shinryoukan
Kise Nago, Okinawa
Japan
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0. Amaldi 6 Homepage[Conference Related]
1. Important Dates 2. Registration 3. Absrtact Submission 4. Accommodation 5. Instructions for presentation6. Program
7. Participants List 8. Proceedings 9. Social Events a. Committees[General Information]
b. Conference Site c. Access Information d. Okinawa Prefecture
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| Poster # | ppt | Presenter name (Affiliation) |
Title | Sesion | |
|---|---|---|---|---|---|
| 1 | * | Gang Bao (Purple Mountain Observatory, Academia Sinica) |
ASTROD I Charging Simulation and Disturbances | Advanced Detectors | |
| 2 | * | Hsien-Hao Mei (National Tsing-Hua Univ.) |
Fiber Mode Cleaner and High-Extinction-Ratio (10^{-9}) Ellipsometer for the Q & A experiment | Advanced Detectors | |
| 3 | * | * | Sheng-Jui Chen (National Tsing Hua Univ.) |
Ellipsometry noise spectrum, suspension transfer function measurement and closed-loop control of the suspension system in the Q & A experiment | Advanced Detectors |
| 4 | Slawomir Gras (The Univ. of Western Australia) |
Optimal mirror design for parametric instability suppression | Advanced Detectors | ||
| 5 | * | Takashi Uchiyama (ICRR, Univ. of Tokyo) |
Cryogenic systems of Cryogenic Laser Interferometer Observatory | Advanced Detectors | |
| 7 | Carlos Frajuca (CEFETSP) |
IMPROVING THE MECHANICAL QUALITY FACTOR IN THE TRANSDUCER IMPEDANCE MATCHERS FOR MARIO SCHENBERG TRANSDUCERS | R&D for Advanced Detectors | ||
| 8 | Carlos Frajuca (CEFETSP) |
STUDYING A NEW SHAPE FOR THE IMPEDANCE MATCHERS IN MARIO SCHENBERG TRANSDUCERS | R&D for Advanced Detectors | ||
| 9 | * | Daisuke Tatsumi (National Astronomical Observatory of Japan |
Online Veto Analysis in TAMA300 | Details of Current Detectors | |
| 10 | * | Joshua Smith (Max-Planck-Institut for Gravitational Physics) |
Projection of GEO600 technical noise to expedite commissioning and enable noise subtraction and GW vetoes | Details of Current Detectors | |
| 11 | * | Michaela Malec (GEO 600) |
Amplitude and frequency noise coupling at GEO 600 | Details of Current Detectors | |
| 12 | * | Noriyasu NAKAGAWA (ICRR. Univ. of Tokyo) |
Influence of radio frequency harmonics in demodulation on a laser interferometer. | Details of Current Detectors | |
| 13 | * | Riccardo DeSalvo (California Institute of Technology) |
Design and prototype tests of a Seismic Attenuation System for the Ad-LIGO Output Mode Cleaner | Details of Current Detectors | |
| 14 | * | Rick Savage (LIGO Project) |
Measurement of thermally induced test mass surface curvature changes in a LIGO 4-km interferometer. | Details of Current Detectors | |
| 15 | * | Stefan Hild (Max-Planck-Institute for Gravitational Physics) |
Detector Characterization of GEO600 during the S4 science run | Status of Current Detectors | |
| 16 | * | Tomotada Akutsu (Univ. of Tokyo) |
Contributions of oscillator noises to the sensitivity of TAMA300 | Details of Current Detectors | |
| 17 | Andrew Moylan (The Australian National Univ.) |
Gravitational lensing of gravitational waves using black hole scattering theory | GW Sources | ||
| 18 | Jose Carlos de Araujo (INPE) |
The star formation rate density and the stochastic background of gravitational waves | GW Sources | ||
| 19 | Ryuichi Fujita (Osaka Univ.) |
New Numerical Methods to Evaluate Homogeneous Solutions of the Teukolsky Equation II | GW Sources | ||
| 20 | Akira Okutomi (Institute for Cosmic Ray Research, Univ. of Tokyo) |
Development of a radiatoin pressure noise interferometer | R&D for Advanced Detectors | ||
| 21 | Alberto Gennai (I.N.F.N.) |
The New Low Noise Control System For The VIRGO Suspensions | R&D for Advanced Detectors | ||
| 22 | Alexander Bunkowski (Univ. of Hannover) |
Diffractive optics for Gravitational Wave detectors | R&D for Advanced Detectors | ||
| 23 | * | Andrea Chincarini (INFN - Genova) |
Superconducting cavity transducer for resonant gravitational radiation antennas | R&D for Advanced Detectors | |
| 24 | * | Angela D. Di Virgilio (INFN-Pisa) |
Discussion about the Low Frequency Facility measurements | R&D for Advanced Detectors | |
| 25 | Benjamin Lee (Univ. of Western Australia) |
Test Mass Suspensions with Reduced Violin String Modes | R&D for Advanced Detectors | ||
| 26 | * | Conor Mow-Lowry (Australian National Univ.) |
Towards the SQL: Off-resonant thermal noise of a niobium-flexure mirror suspension | R&D for Advanced Detectors | |
| 27 | * | Damien Mudge (Univ. of Adelaide) |
A High Power Nd:YAG Laser for Advanced Interferometric Detectors | R&D for Advanced Detectors | |
| 28 | David Blair (Univeristy of Western Australia) |
Parametric Instability and Thermal Lensing Experiments at the Gingin High Power Test Facility | R&D for Advanced Detectors | ||
| 29 | * | Stefan Gossler (Australian National Univ.) |
Control systems for advanced interferometer configurations | R&D for Advanced Detectors | |
| 30 | * | Eu-Jeen Chin (Univ. of Western Australia) |
AIGO High Performance Compact Vibration Isolation System | Details of Current Detectors | |
| 31 | * | * | Filippo Martelli (Univ. of Urbino and INFN Florence) |
Measurement of the thermoelastic properties of crystalline Si fibers | R&D for Advanced Detectors |
| 32 | * | Fulvio Ricci (Univ. of Rome La Sapienza) |
Vibration Free Cryostat for cooling suspended mirrors | R&D for Advanced Detectors | |
| 33 | * | Fumiko Kawazoe (Ochanomizu Univ.) |
The experimental plan for a 4m Resonant Sideband Extraction interferometer | R&D for Advanced Detectors | |
| 34 | * | Gabriele Vajente (Scuola Normale Superiore Pisa) |
The Design and Performance of an Anderson-Technique Based Alignment System | R&D for Advanced Detectors | |
| 35 | * | Geppo Cagnoli (IGR - Univ. of Glasgow) |
Silica suspension and coating developments for Advanced LIGO | R&D for Advanced Detectors | |
| 36 | * | Giovanni Mazzitelli (Laboratori Nazionali di Frascati) |
First result in low temperature regime of the RAP experiment | R&D for Advanced Detectors | |
| 37 | * | Hiroaki Yamamoto (California Institute of Technology) |
Simulation tools for future interferometers | R&D for Advanced Detectors | |
| 38 | Jerome Degallaix (ACIGA - UWA) |
Comparison sapphire – silicon as test mass candidate for laser interferometer from 300K to 5K | R&D for Advanced Detectors | ||
| 39 | * | Junichi Miura (Univ. of Electro-Communications) |
Development of a fiber-MOPA system for the light source of the gravitational wave antenna | R&D for Advanced Detectors | |
| 40 | * | Kazuhiro Yamamoto (Institute for Cosmic Ray Research) |
Measurement of vibration of top of suspension in cryogenic interferometer with operating cryocoolers | R&D for Advanced Detectors | |
| 41 | * | Keiko Kokeyama (Ochanomizu Univ.) |
Downselect of signal extraction schemes for LCGT | R&D for Advanced Detectors | |
| 42 | Lee Benjamin (Univ. of Western Australia) |
Cavity Control System for High Optical Power Interferometers | R&D for Advanced Detectors | ||
| 43 | Li Ju (Univ. of Western Australia) |
Comparison of scattering, absorption and birefringence in sapphire test masses | R&D for Advanced Detectors | ||
| 44 | * | Masao Tokunari (Institute for Cosmic Ray Research) |
Measurement of optical properties of single-crystal sapphire substrates for gravitational wave detection | R&D for Advanced Detectors | |
| 45 | * | Masatake Ohashi (The Univ. of Tokyo) |
Development of vertical interferometer | R&D for Advanced Detectors | |
| 46 | Nergis Mavalvala (MIT) |
Squeezed state generation using ponderomotive rigidity in an interferometer | R&D for Advanced Detectors | ||
| 47 | * | Norna Robertson (Stanford Univ.) |
Update on Aspects of the Suspension Design for Advanced LIGO | R&D for Advanced Detectors | |
| 48 | * | Norna Robertson (Stanford Univ.) |
Kelvin Probe Measurements: Investigations of the Patch Effect with Applications to ST7 and LISA | Space Detectors | |
| 49 | Odylio Aguiar (INPE - BRAZIL) |
DEVELOPMENT OF A VERY HIGH SENSITIVITY PARAMETRIC TRANSDUCER FOR THE MARIO SCHENBERG GRAVITATIONAL WAVE DETECTOR | R&D for Advanced Detectors | ||
| 50 | Odylio Aguiar (INPE - BRAZIL) |
RESPONSE OF THE MARIO SCHENBERG DETECTOR TO SIMULATED GRAVITATIONAL WAVE SIGNALS WITH NOISE | Data Analysis | ||
| 51 | Pablo Barriga-Campino (Univ. of Western Australia) |
Reduction of Thermally Induced Astigmatism in Mode-Cleaners for Advanced Interferometers | R&D for Advanced Detectors | ||
| 52 | * | Peter Beyersdorf (Stanford Univ.) |
Flat-top mode in an optical cavity with a deformable mirror | R&D for Advanced Detectors | |
| 53 | * | Renzo Vaccarone (I.N.F.N.) |
Gain and noise analysis of HEMT amplifiers from room temperature to superfluid He. | R&D for Advanced Detectors | |
| 54 | * | Ryutaro Takahashi (National Astronomical Observatory) |
Seismic Attenuation System (SAS) for TAMA | R&D for Advanced Detectors | |
| 55 | * | Sandor Nietzsche (Friedrich-Schiller-Universitaet Jena) |
Cryogenic Q-factor measurement of optical substrate materials | R&D for Advanced Detectors | |
| 56 | * | Shigenori Moriwaki (Univ. of Tokyo) |
Control experiment of a frequency-tunable ring cavity used as an output mode cleaner for a Michelson interferometer | R&D for Advanced Detectors | |
| 57 | * | Shihori Sakata (Ochanomizu Univ.) |
The study of a quantum non-demolition interferometer using a ponderomotive squeezing | R&D for Advanced Detectors | |
| 58 | * | SHINJI MIYOKI (Institute for Cosmic Ray Research, Univ. of TOKYO) |
Manufacturing of a 10-km-scale radius-of-curvature surface using a thin-film coating technique | R&D for Advanced Detectors | |
| 59 | * | Shuichi Sato (National Astronomical Observatory of Japan) |
Diagonalizing of length sensing matrix for resonant sideband extraction interferometer with broadband operation. | R&D for Advanced Detectors | |
| 60 | * | Stuart Reid (Univ. of Glasgow) |
Investigations of silicon as a material for suspension elements | R&D for Advanced Detectors | |
| 61 | * | Takayuki Tomaru (High Energy Accelerator Researh Organization) |
Study of optical dumper used in high vacuum system of interferometric gravitational wave detectors | R&D for Advanced Detectors | |
| 62 | * | Wei-Tou Ni (Purple Mountain Observatory) |
Picowatt and femtowatt weak-light phase locking, and its application to deep space laser ranging | R&D for Advanced Detectors | |
| 63 | * | Wei-Tou Ni (Purple Mountain observatory) |
ASTROD and ASTROD I: Progress Report | Space Detectors | |
| 64 | * | Yoichi Aso (Univ. of Tokyo) |
Active vibration isolation using a Suspension Point Interferometer | R&D for Advanced Detectors | |
| 65 | * | Antonio F. Garcia Marin (Albert-Einstein-Institute) |
Automatic alignment procedure and in-orbit diagnostic modes for the LTP interferometer | Space Detectors | |
| 66 | * | Antonio Pulido Paton (Purple Mountain Observatory) |
The Low Frequency Sensitivity to Gravitational Waves for ASTROD | Space Detectors | |
| 67 | Benjamin Sheard (The Australian National Univ.) |
Experimental test of arm locking for LISA with an optical fibre delay line | Space Detectors | ||
| 68 | de Vine Glenn (Center for Gravitational Physics, ANU) |
Cavity-enhanced mechanical-noise free iodine spectroscopy for LISA laser frequency stabilisation | Space Detectors | ||
| 69 | Gianni Bagni (Univ. of Urbino and INFN sez. Firenze-Urbino) |
Numerical model of a mechanical prototype for the LISA PathFinder on-ground tests. | Space Detectors | ||
| 70 | * | Leone Bosi (Dipartimento di Fisica and INFN di Perugia) |
Possible GW signal induced by CME passage through LISA | Space Detectors | |
| 71 | * | Kenji Numata (NASA/GSFC) |
Thermal Noise Limit in Frequency Stabilization of Lasers with Rigid Cavities | Space Detectors | |
| 72 | * | KE-XUN SUN (Stanford Univ.) |
Grating Angle Magnification Enhanced Angular and Integrated Sensors for LISA Applications | Space Detectors | |
| 73 | * | KE-XUN SUN (Stanford Univ.) |
LED Deep UV Source for Charge Management | Space Detectors | |
| 74 | Linqing Wen (Max Planck Institut fuer Gravitationsphysik) |
Detecting Extreme-Mass-Ratio-Inspirals With LISA Using Time-Frequency Methods | Space Detectors | ||
| 75 | * | Lorenzo Marconi (Univ. of Pisa & INFN Firenze-Urbino) |
Ground Based Test for LISA and LISA Pathfinder | Space Detectors | |
| 76 | * | Mauro Hueller (Univ. of Trento) |
Geodesic motion of LISA test masses: the LTP experiment | Space Detectors | |
| 77 | * | Michael Troebs (Max Planck Institute for Gravitational Physics) |
Laser development for LISA | Space Detectors | |
| 78 | * | Sachie Shiomi (National Tsing Hua Univ.) |
Acceleration disturbances due to local gravity gradients in ASTROD I | Space Detectors | |
| 79 | * | Vinzenz Wand (Albert Einstein Institut) |
Noise sources in the LTP interferometer | Space Detectors | |
| 80 | * | Volker Leonhardt (NASA Goddard Space Flight Center) |
Laser frequency stabilization with molecular iodine and application to LISA | Space Detectors | |
| 81 | * | Kazuhiro Hayama (National Astronomical Observatory of Japan) |
Wavelet-based Method to Monitor Non-Stationary Signals in an Interferometer | Data Analysis | |
| 82 | * | Koji ISHIDOSHIRO (Univ. of Tokyo) |
Systematic survey of monitor signals to reject fake events | Data Analysis | |
| 83 | * | Lucio Baggio (ICRR, Univ. of Tokyo) |
Coincidence search in heterogeneous GW networks | Data Analysis | |
| 84 | Nadja Magalhaes (ITA) |
Can lightnings be a noise source for a gravitational wave spherical antenna? | Data Analysis | ||
| 85 | * | Nobuaki Sato (KEK) |
A data analysis processor with an FPGA for gravitational-wave event searches | Data Analysis | |
| 86 | * | * | Norichika Sago (Osaka Univ.) |
Coherent analysis by using multiple interferometric detectors | Data Analysis |
| 87 | Wataru Hikida (Yukawa Institute for Theoretical Physics) |
Error estimates of template using BH perturbation for extreme mass binary system | Data Analysis | ||
| 88 | * | Yoshiaki Himemoto (Univ. of Tokyo) |
Detecting a stochastic background in the presence of non Gaussianity by the generalized cross correlation statistic | Data Analysis | |
| 89 | Sergey Klimenko (Univ. of Florida) |
Likelihood analysis of un-modeled gravitational wave signals for a network of interferometric detectors | Data Analysis | ||
| 91 | * | Charlie Torres (Univ. of Texas at Brownsville) |
Progress on a detection algorithm for longer-lived gravitational wave bursts | Data Analysis | |
| 92 | Soma Mukherjee (Univ. of Texas at Brownsville) |
Analysis of noise floor non-stationarity in LIGO S4 data | Data Analysis | ||
| 93 | * | Craig Robinson (Cardiff Univ.) |
A low latency pipeline for inspiraling compact binary searches | Data Analysis | |
| 95 | * | Stephen Fairhust / Hirotaka Takahashi (Univ. of Wisconsin-Milwaukee / Osaka City Univ.) |
Status of the joint LIGO-TAMA inspiral analysis | Data Analysis | |
| 96 | * | Gareth Jones (LIGO Scientific Collaboration) |
Searching for spinning black hole binaries in S3 LIGO data | Data Analysis | |
| 97 | * | Thomas Cokelaer (Cardiff University) |
Report on the binary black hole inspiral search in S3 LIGO data | Data Analysis | |
| 98 | * | Andres Rodriguez (Louisiana State Univ.) |
A Time Series Waveform Consistency Test for Binary Inspirals using LIGO data | Data Analysis | |
| 99 | * | Chad Hanna (Louisiana State Univ.) |
Vetoing false alarms in LIGO's search for binary neutron star systems | Data Analysis | |
| 100 | Patrick Brady (Univ. of Wisconsin-Milwaukee) |
Search for inspiralling binary neutron stars in S3 and S4 data | Data Analysis | ||
| 101 | * | TOMOMI AKUTSU (ICRR, Tokyo University) |
Current status of burst gravitational wave analysis of TAMA300 data | Data Analysis | |
| 102 | * | Innocenzo M. Pinto (Univ. of Sannio at Benevento, The Waves Group) |
OPTIMUM DETECTION OF PERMANENT GRAVITATIONAL WAVES:THE SEQUENTIAL PARADIGM | Data Analysis | |
| 103 | * | Martin Hewitson (Max-Planck-Institut) |
Optimal time-domain calibration of the dual-recycled GEO600 | Data Analysis | |
| 104 | Leone Bosi (VIRGO - INFN Perugia) |
A parallel in-time analisys system for Virgo | Data Analysis | ||
| 105 | Erik Katsavounidis (MIT) |
Searches for Gravitational Wave Bursts with LIGO's S2 and S3 Science Runs | Data Analysis | ||
| 106 | Ik Siong Heng (Unversity of Glasgow) |
Searching for Burst Gravitational Waves with a LIGO-GEO network | Data Analysis | ||
| 107 | andre-claude clapson (laboratoire de l'accelerateur lineaire) |
First LIGO-Virgo network analysis cooperation on gravitational wave bursts | Data Analysis | ||
| 108 | * | Rejean Dupuis (Calteh) |
Targeted searches for gravitational waves from radio pulsars | Data Analysis | |
| 109 | * | Igor Yakushin (LIGO Livingston Observatory, Caltech) |
Status of the untriggered burst search in S4 LIGO data | Data Analysis | |
| 110 | Leone Bosi (INFN) |
Mechanical loss investigation in Ta2O5/SiO2 dielectric coatings | R&D for Advanced Detectors | ||
| 111 | * | John Whelan (Loyola University New Orleans) |
Stochastic Background Search with ALLEGRO and LIGO Science Data | Data Analysis | |
| 112 | * | William J. Weber (Universita' di Trento) |
Experimental investigation of electrostatic dissipation and its impact on LISA free fall | Space Detectors | |
| 113 | * | Masaki Ando (The University of Tokyo) |
Upper limits on gravitational wave bursts radiated from stellar-core collapses in our Galaxy | Data Analysis | |
| 114 | * | Szabolcs Marka (Columbia University) |
Prospects of gravitational wave data mining and exploration via genetic algorithms | Data Analysis | |
| 115 | * | Patrick Sutton (LIGO, Caltech) |
Upper Limits from LIGO and TAMA on Gravitational-Wave Bursts | Data Analysis |
Mail to: amaldi6@nao.ac.jp
Last Update:
3 Jun, 2005