Your search keyword '"S. Kashiguine"' showing total 3 results

1. The assembly of the silicon tracker for the GLAST beam test engineering model

Author

K. Yamamoto, G. Giebels, A. Webster, Sean P. Stromberg, E. Do Couto E Silva, E. Atwood, W. Atwood, N. Cotton, M. Nikolaou, B. Feerick, E. Ponslet, Elliott D. Bloom, R. P. Johnson, Kazuhisa Yamamura, V. Chen, T. Ohsugi, Warner A. Miller, J. Clark, G. Godfrey, G. A. Beck, W. Kroeger, S. Yoshida, T. Kamae, O. Millican, Gwelen Paliaga, H. F.W. Sadrozinski, J.A. Hernando, D. Tournear, J. Broeder, E.N. Spencer, B. Bhatnager, M. Nordby, E. Swensen, G. Winkler, P. P. Allport, W.A. Rowe, S. Kashiguine, M. Takayuki, T. Handa, M. Hirayama, and C. Milbury

Subjects

Physics, Nuclear and High Energy Physics, Silicon, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, chemistry.chemical_element, law.invention, Telescope, Reliability (semiconductor), Optics, chemistry, law, Satellite, Aerospace engineering, business, Instrumentation, Quality assurance, Beam (structure), Silicon microstrip detectors

Abstract

The silicon tracker for the engineering model of the GLAST Large Area Telescope (LAT) to date represents the largest surface of silicon microstrip detectors assembled in a tracker (2.7 m 2 ). It demonstrates the feasibility of employing this technology for satellite based experiments, in which large effective areas and high reliability are required. This note gives an overview of the assembly of this silicon tracker and discusses in detail studies performed to track quality assurance: leakage current, mechanical alignment and production yields.

Published

2001

2. The silicon tracker of the beam test engineering model of the GLAST large-area telescope

Author

K. Yamamoto, E. Atwood, M. Nikolaou, Hartmut Sadrozinski, W. B. Atwood, B. Feerick, B. Giebels, Sean P. Stromberg, E. Do Couto E Silva, V. Chen, W. Kroeger, T. Ohsugi, S. Yoshida, E.N. Spencer, T. Kamae, S. Kashiguine, Gwelen Paliaga, Kazuhisa Yamamura, Elliott D. Bloom, B. Bhatnager, A. Webster, O. Millican, N. Cotton, R. P. Johnson, E. Ponslet, D. Tournear, J. Broeder, J. Clark, Warner A. Miller, G. Godfrey, W.A. Rowe, J.A. Hernando, E. Swensen, G. Winkler, T. Handa, M. Nordby, M. Takayuki, M. Hirayama, and C. Milbury

Subjects

Physics, Nuclear and High Energy Physics, Photon, Silicon, business.industry, Gamma ray, chemistry.chemical_element, law.invention, Telescope, Optics, chemistry, law, Satellite, business, Instrumentation, Silicon microstrip detectors, Beam (structure), Communication channel

Abstract

The silicon tracker for the engineering model of the GLAST Large Area Telescope(LAT) has at least two unique features: it employs self triggering readout electronics, dissipating less than 200 mu-W per channel and to date represents the largest surface of silicon microstrip detectors assembled in a tracker (2.7 m{sup 2}). It demonstrates the feasibility of employing this technology for satellite based experiments, in which low power consumption, large effective areas and high reliability are required. This note describes the construction of this silicon tracker, which was installed in a beam test of positrons, hadrons and tagged photons at SLAC in December of 1999 and January of 2000.

Published

2001

3. Detector development for Proton Computed Tomography (pCT)

Author

M. Scaringella, Scott Penfold, Bela Erdelyi, Scott McAllister, S. Kashiguine, F. Martinez-McKinney, D. Fusi, F. Hurley, Keith E. Schubert, H. F.W. Sadrozinski, George Coutrakon, B. Colby, David Steinberg, Reinhard W. Schulte, J. Missaghian, R. P. Johnson, Vladimir Bashkirov, A. Zatserklaniy, and V. Rykalin

Subjects

Physics, Proton, Physics::Instrumentation and Detectors, business.industry, Radiography, Physics::Medical Physics, Detector, Iterative reconstruction, Tracking (particle physics), Imaging phantom, Optics, Physics::Accelerator Physics, Nuclear medicine, business, Proton therapy, Energy (signal processing)

Abstract

Proton Computed Tomography (pCT) is being developed in support of proton therapy and treatment planning. The aim of pCT, to reconstruct an accurate map of the stopping power (S.P.) in a phantom and, in the future, in patients, is being pursued with a diverse list of detector systems, using the entire arsenal of tracking and energy detectors developed for High Energy Physics (HEP). The first radiographs and 3D images are being reconstructed with prototype detectors, which will be described. Most of the existing systems are being upgraded to higher proton fluxes to reduce the scanning time.

Published

2011