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Table of content to the book "400+ times.."

Technical-Scientific book by D. Crosetto: "400+ times Improved PET efficiency Reference Section"  

(Document in PDF) References for the book written by Dario Crosetto...<hr>

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Mankoff, D.A., et al.: A local coincidence triggering system for PET tomographs composed of large-area position-sensitive detectors. IEEE Trans. Nucl. Sci., vol. 37:730-736, 1990.
[156]
Crosetto, D., “System Design and Verification Process for LHC Programmable Trigger Electronics” IEEE NSS-MIC Seattle (WA) Oct. 24-30, 1999. http://www.3d-computing.com/pb/nss99.pdf
[157]
Crosetto, D., “Massively Parallel-Processing System with 3D-Flow Processors.” IEEE Computer Society. 0-81816-6322-7194, pp.355-369.
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Crosetto, D. "High-Speed, Parallel, Pipelined, Processor Architecture for front-end Electronics, and Method of Use Thereof." LHCb 96-2, TRIG 96-1
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Paans, A.M.J., et al.: The imaging of positron emitters in single photon and coincidence mode: evaluation of SPECT and PET systems. 18th annual International Conference of IEEE Engineering in Medicine and Biology Society, Amsterdam 1996, pp. 846-847.
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Crosetto, D.: Detailed design of the digital electronics interfacing detectors… LHCb 99-006, 5 May, 1999 CERN – Geneva.
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[162 ] Anger R.T.: The Anger scintillation camera, Rao D.V., Ed.: Physics of Nuvlear Medicine, Recent Advances, New York, American Institute of Physics, 1984.
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Crosetto, D.: LHCb base-line level-0 trigger 3D-Flow implementation.” Nuclear Instruments and methods in physics research, Section A 436 (1999) 341-385.
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Crosetto, D.: Real-time system design environment for multi-channel high-speed data acquisition system and pattern recognition. 11th IEEE Real time conference, Santa Fe, New Mexico, USA, 14-18 June 1999. pp. 329-336.
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Jones, F.Williams, PETLINK, CTI System, Inc. 810 Innovation Dr. Knoxville, TN 37932-2571. www.cti-pet.com/bjones.nsf.
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http://depts.washington.edu/~simset/html/simset_main.html (SimSET: “Simulation System for Emission Tomography”, a simulation package that uses Monte Carlo techniques to model the physical processes and instrumentation used in emission imaging.
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Some Bibliographical References to Crosetto's Work  

[1]
Crosetto, D.: 400+ times improved PET efficiency for lower-dose radiation, low-cost cancer screening. ISBN 0-9702897-0-7. 2000. Available at Amazon.com
[2]
Crosetto, D.: LHCb base-line level-0 trigger 3D-Flow implementation. Nuclear Instrument and Methods in Physics Research, Sec. A, vol. 436 (1999) pp. 341-385.
[3]
Crosetto, D.: "Ignored Discovery Now Proven Capable of Saving Millions of Lives from Premature Cancer Death Demands Rethinking the Direction of Research" Book: Astroparticle, Particle and Space Physics, Detectors and Medical Physics Applications. Editor: World Scientific, 2008. http://www.crosettofoundation.com/uploads/134.pdf
[4]
Crosetto, D. Saving lives through early cancer detection: Breaking the current PET efficiency barrier with the 3D-CBS.” 2001. www.3d-computing.com/pb/3d-cbs.pdf
[5]
Crosetto, D.: "Rethinking Positron Emission Technology for Early Cancer Detection" Book: Astroparticle, Particle and Space Physics, Detectors and Medical Physics Applications. Editor: World Scientific, 2006, pp. 692-696.
[6]
Crosetto, D.: “Come Vincere il Cancro”. Book. Ed. Clavilux. 2005. Available at www.clavilux.it
[7]
Crosetto, D., U.S. Patent No. 7,051,309 B1. May 23, 2006
[8]
Crosetto, D.: A modular VME or IBM PC based data acquisition system for multi-modality PET/CT scanners of different sizes and detector types. Presented at the IEEE Nuclear Science Symposium and Medical Imaging Conference, Lyon, France, 2000, IEEE-2000-563, http://www.3d-computing.com/pb/ieee2000-563.pdf.
[9]
Crosetto, D.: Real-time, programmable, digital signal-processing electronics for extracting the information from a detector module for multi-modality PET/SPECT/CT scanners. Presented at the IEEE Nuclear Science Symposium and Medical Imaging Conference, Lyon, France, 2000, IEEE-2000-567, http://3d-computing.com/pb/ieee2000-567.pdf.
[10]
Crosetto, D.: “3D-Flow DAQ IBM PC board for Photon Detection in PET and PET/CT” IEEE-NSS-MIC-2003. Conference Record. M3-130.
[11]
Crosetto, D.: “The 3-D Complete Body Screening (3D-CBS) Features and Implementation” IEEE-NSS-MIC-2003. Conference Record. M7-129. www.3d-computing.com/pb/IEEE2003_M7-129p.pdf.
[12]
Crosetto, D.: “Channel Reduction and Time Coincidence IBM PC board for PET” IEEE-NSS-MIC-2003. Conference Record. M6-131.
[13]
Crosetto, D.: "Development of an Innovative Three-Dimensional Complete Body Screening Device - 3D-CBS" Book: Astroparticle, Particle and Space Physics, Detectors and Medical Physics Applications. Editor: World Scientific, 2004, pp. 350-359.
[14]
See review of Crosetto's book at http://www.3d-computing.com/pb/review_scient.pdf
[15]
See Final Report of the committee who reviewed Crosetto’s innovative technology at www.3d-computing.com/pb/Review_rep.pdf.
[16]
Crosetto, D. e Vigna, V.: PRIMO: la SALUTE. Ed. Associazione Vita, Corso Garibaldi, 78 – 27013 Chignolo Po (PV)
[17]
Crosetto, D.: A fast cluster finding system for future HEP experiments. Nuclear Instruments and Methods in Physics Research A311 (1992) pp. 49-56.
[18]
Crosetto, D.: “System Design and Verification Process for LHC Programmable Trigger Electronics” IEEE NSS-MIC. Seattle (WA) Oct. 24-30, 1999.
[19]
Crosetto, D.: Digital Signal Processing in high energy physics. Lecture before the CERN School of Computing at Yesermonde, Belgium 2-15 September 1990. Publ. by CERN 91-05. 14 May 1991.
[20]
Buono, S. and Crosetto, D.: “Test results of Real-Time Algorithms Executed on FDPP with SPACAL data.” CERN/ECP 90-6, 5 October, 1990.
[21]
Crosetto, D.: “High-Speed, Parallel, Pipelined, Processor Architecture for front-end Electronics, and Method of Use Thereof.” LHCb 96-2, TRIG 96-1. CERN, Geneva.
[22]
Conetti, S. e Crosetto, D.: “Implementing the Level-0 Trigger,” IEEE Trans. Nucl. Science 43, 170 (1996).
[23]
Crosetto, D.: U.S. Patent No. 5,937,202 August 10, 1999.
[24]
Crosetto, D.: “Interfacing detectors to triggers and DAQ electronics.” Note LHCB 99-006, 1999, pp. 1-59. Available at the European Center for Nuclear Research (CERN) in Geneva, Switzerland.
[25]
Crosetto, D.: “Real-Time system design environment for multichannel high-speed data acquisition system and pattern-recognition.” IEEE Real Time conference, Santa Fe, (NM) June 14-18, 1999.
[26]
Crosetto, D.: “System design and verification process for LHC programmable trigger electronics.” IEEE NSS-MIC Seattle (WA) Oct. 24-30, 1999.
[27]
Crosetto, D.: “Fast Particles Identification in Programmable form at Level-0 Trigger by means of the 3D-Flow System.” Fourth Workshop on Electronics for LHC Experiments. Pp. 517-522. September 21-25, 1998.
[28]
M. Botlo, D. Crosetto, et al.: The STAR cluster-finder ASIC. Proc. Xth IEEE Real Time Conference 1997, Beaune, France, September 22-26, 1997.
[29]
Crosetto, D.: Ninth Conference on Real-Time Computer Applications in Nuclear, Particle, and Plasma Physics. MSU, East Lansing, MI, May 23-26, 1995. IEEE Transactions in Nuclear Science, Feb. 1996.
[30]
Crosetto, D.: U.S. Patent No. 5,590,284
[31]
Alderighi, M, Crosetto, D., et al.: (ICA3PP-95). IEEE 0-7803-2018-2195. Vol. 2, pp. 761-763. 1995.
[32]
Crosetto, D.: "Massively Parallel-Processing System with 3D-Flow Processors.” Published by IEEE Computer Society. 0-81816-6322-7194, pp. 355-369. 1994.
[33]
Crosetto, D.: U.S. Patent No. 5,331,315
[34]
Crosetto, D.: "Programmable Level-1 Trigger with 3D-Flow Array," Computing in HEP, San Francisco, CA, 21-27 April 1994. Editor: S.C. Loren, pp. 57-61
[35]
Crosetto, D.: "Digital Programmable Level-1 Trigger for Calorimeter with 3D-Flow Processor Array," IV International Conference on Calorimetry in HEP, 19-25 Sept, 1993 - La Biodola, Elba, Italy.
[36]
Crosetto, D.:"Digital Programmable Level-1 Trigger with 3D-Flow Assembly," SSCL-Preprint-445, August 1993, submitted to Nuclear Instruments and Methods in Physics Research.
[37]
Crosetto, D.:"Real-Time Tracking with a 3D-Flow Processor Array." Workshop on B Physics at Hadron Accelerators, June 21-July2, 1993. Snowmass, Colorado. SSCL-Preprint-516
[38]
Crosetto, D.: "Data Stream Pipeline 3D-Flow Processor System for a Programmable Level-1 Trigger." Eight Conference on Real-Time Computer Applications in Nuclear, Particle and Plasma Physics, Vancouver, June 8-11, 1993
[39]
Crosetto, D.: "Parallel-Processing system with 3D-Flow," Proceedings of the International Conference on Electronics for Future Colliders, May 4-6, 1993, LeCroy Corporation, Chestnut Ridge, New York.
[40]
“Technical Design Report” Gamma, Electrons, and Muons Collaboration to the Superconducting Super Collider Laboratory. July 31, 1993. GEM-TN-93-262 – SSCL-SR-1219. From page 7-10 to 7-14.
[41]
Crosetto, D.: "General Programmable Level-1 Trigger with 3D-Flow Assembly System for Calorimeters of Different Sizes and Event Rates. SSCL-607, Dec. 1992. Submitted to Nuclear Instruments and Methods in Physics Research.
[42]
Crosetto, D.: "A modular parallel processing system for trigger decision and DAQ in HEP experiments," Nuclear Instruments and Methods in Physics Research, A315, (1992), 487-490.
[43]
Crosetto, D.: "A new approach in device testing," NASECODE VIII, Proceedings of the Eight International Conference on the Numerical Analysis of Semiconductor Devices and Integrated Circuits, May 19-22, 1992. Vienna, Austria
[44]
Crosetto, D.: "3D-Flow Processor for a Programmable Level-1 Trigger," Computing in High Energy Physics, CHEP92, 21-25 September, 1992, Annecy, France, 803-806.
[45]
Crosetto, D.: "Calorimeter Programmable Level-1 Trigger," III International Conference on Calorimetry in High Energy Physics, Corpus Christi, Sept. 29-Oct. 2, 1992. SSCL-Preprint-180, October 1992.
[46]
Crosetto, D.: "3D-Flow Processor for a Calorimeter Programmable Level-1 Trigger," SSCL-Preprint-165, TNS Conference Issue, November 1992
[47]
Crosetto, D.: "3D-Flow Processor for a Programmable Level-1 Trigger," SSCL-Preprint-164, Nuclear Science Symposium (NSS), Medical Imaging Conference (MIC), Orlando, Florida, October 25-31. 1992
[48]
Crosetto, D.: "A Fast Cluster Finding System for Future HEP Experiments," Computing in High Energy Physics, 1991, CHEP91, Tsukuba, 229-236.
[49]
Buono, S., Crosetto, D.: "Fast Digital Parallel Processing Module Software Development," CERN/ECP 90-22, 21 December 1990.
[50]
Crosetto, D.:"A Fast Cluster Finding System for Future HEP Experiments," CERN/ECP 90/14, 30 November 1990.
[51]
Crosetto, D.: "A software package for testing and debugging the Fast Digital Data Processor board." INFN report (one co-author) - INFN/TC-88/12. 1988.
[52]
Crosetto, D.: "A fast zero suppression algorithm for the Forward Electromagnetic Calorimeter (FEMC), implemented on DSP56000."DAS-DELPHI report (two co-authors) - DELPHI/88-40 DAS-82, June 2nd 1988.
[53]
Crosetto, D.: - Patent (Italy) - Sistema modulare per il trattamento in parallelo, in forma digitale, di algoritmi matematici.
[54]
Crosetto, D.: "Parallel arrays of digital signal processor as central decision elements for upper level triggers in High Energy Physics experiments." IEEE Transaction on Nuclear Science (three co-authors) - February, 1988. -
[55]
Crosetto, D.: "A possible hardware implementation of the HPC II level trigger." DAS-DELPHI report - DELPHI/87-100 DAS-65, December 1st 1987.
[56]
Crosetto, D.: "Use of Digital Signal Processors (DSP) in High Energy Physics Experiments." CERN "Mini and Micro Computer Newsletter", - October, 1987
[57]
Crosetto, D.: "A Fast Digital Data Processor for the FEMC trigger. (VME version), User's Manual, rev. 1.0." CERN-DELPHI report - DELPHI/87 - DAS-58 July 1st, 1987
[58]
Crosetto, D.: "Fast Digital Data Processor. A modular system for parallel digital processing algorithms (VME version). FDDP" CERN-EP preprint - CERN-EP/87-151, August 25th, 1987.
[59]
Crosetto, D. et al.: "Realization of an automatic set-up to measure electrical characteristics of solid state detectors". - INFN report (four co-authors) - INFN/TC-86/7. 1986.
[60]
Crosetto, D.: "Automatized microscope for nuclear emulsion measurements." Nuclear Track, Vol. 12 Nos 1-6, pp. 253-255, 1986 (three co-authors) -
[61]
Crosetto, D.: "Proposal for the second and third level trigger of the Forward ElectroMagnetic Calorimeter. CERN-DELPHI report (five co-authors) - DELPHI/86-100 DAS-42, November 1986
[62]
Crosetto, D.: "A low cost microprocessor development system for laboratory use based on STD-BUS, Z80-CPU and CP/M operating system. MICRO-LEARN"-INFN report (one co-author) - INFN/TC-85/5.
[63]
Crosetto, D.: etal.: "Understanding a new idea for a Cancer Screening device" Available at Amazon.com, ISBN 0-9702897-1-5. Pub. October 12, 2000.
[64]
Levine, M., Crosetto, D. et al.: “The Star Cluster-Finder ASIC” LeCroy. http://www.lecroy.com/lrs/EPP/levine.htm
[65]
Crosetto, D.: "Programmable Level-1 Trigger with Digital Filtering," SDC note, SDC-93-488, 23 April
[66]
Crosetto, D.: "Calorimeter Programmable Level-1 Trigger 3584 Trigger Tower 3D-Flow System Assembly," SDC note, SDC-92-391, 10 December 1992.
[67]
Crosetto, D.: "3D-Flow Processor for a Programmable Level-1 Trigger (Feasibility Study)," SSCL-601, October 1992.
[68]
Crosetto, D.: "3D-Flow Processor Preliminary Technical Specifications," SSCL-594, October 1992.
[69]
Crosetto, D., L. Love: "Fully Pipelined and Programmable Level-1 Trigger," SSCL-576,. July 1992.
[70]
Crosetto, D.: "Calorimeter Programmable Level-1 Trigger 1250 Trigger Tower 3D-Flow Assembly System," GEM note, GEM-TN-92-248, December 1992.
[71]
Crosetto, D.: "A New Approach in Device Testing," SDC note, SDC-92-228, February, 1992
[72]
Crosetto, D.: "Utilizzo di Digital Signal Processors (DSP) in High Energy Physics Experiments" .NOTIZIARIO INFN, - June/Sept. 1987.
[73]
Crosetto, D.: "A microcomputer controlled PAL programmer." INFN report (one co-author) - INFN/TC-85/15.
[74]
Crosetto, D. et al.: "Digitalized microscope for the Beauty search experiment WA75." INFN- Internal note (two co-authors) - June 1984

 
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