41. Imaging Science And Technology, IBM Watson Research Projects in imaging science and technology. icon of DreamSpace DreamSpace smartroom for deviceless multimodal natural interaction. http://www.research.ibm.com/imaging/

Projects in imaging science and technology DreamSpace smartroom for deviceless multimodal natural interaction natural interactivity interact with information as using skills that humans already have Imaging petroleum geology and geophysics Petroleum geology and geophysics images Animations related to petroleum geology and geophysics Useful links IBM petroleum industry solutions GBRN global basin research network geosciences The world-wide web virtual library: earth sciences Pharmaceutical visualization Computational chemistry Computer graphics in art and science Cover shots Other resources on the Net IBM Almaden research center visualization lab Research in electro-holographic displays : interactive 3-D holography IBM Visualization Data Explorer (DX) Numerically intensive computing - simulations involving astrophysics, fluid dynamics, electronic structure, immune systems, weather modeling last update: 1999 Apr IBM T. J. Watson Research Center , Yorktown Heights, New York, USA. IBM research Products and projects IBM home page Order ... (TM)

42. IBM Research: Petroleum Geology And Geophysics, Imaging Science And Technology ulisses@watson.ibm.com IBM research imaging science and technology IBM home page Order Search Contact IBM Help (C) (TM) . http://www.research.ibm.com/imaging/geo/images/images.html

Petroleum Geology and Geophysics Images Thermal anomaly induced by a salt tongue in the surrounding sediments. Red and blue indicate respectively hotter and colder than a temperature distribution when no salt is present. For more details see Mello et al. (1995). Thermal anomaly induced by a salt diapir and associated effects on maturation. The green, red and yellow solid lines indicates the top of oil window, peak of oil generation, and bottom of oil windows, respectively. Black thin lines represents the heat flow streamlines deflected by the salt diapir. For more details see Mello et al. (1995) and Mello et al. (1994). Porosity predicted for the Jurassic time (144 Ma) in the Gulf of Mexico basin. For more details see Mello and Karner (1994). This image will be featured in the next year "Beauty of Physics" calendar of the American Institute of Physics - AIP. Predicted maturation for the structural top of the formation equivalent to Smackover. Predicted maturation for the Gulf of Mexico basin at present day time. The red mesh represents the peak of oil generation. Predicted evolution of overpressure for the base of Lower Cretaceous sediments. There were two major pulses of overpressure production: 1) Late Cretaceous, and 2) Quaternary.

43. Research Themes - Imaging Science Research focuses on the use of imaging techniques and their derivativesto measure various components of body composition. This http://www.leeds.ac.uk/healthcare/research/researchthemes/Imagscience.htm

Imaging Sciences Imaging Sciences Medicines Management Older People Public Health ... EREG Research focuses on the use of imaging techniques and their derivatives to measure various components of body composition. This work is carried out in the Centre for Bone and Body Composition Research and is directed by Dr John Truscott. Further evidence-based research has just been started within the Imaging Sciences Group and is investigating both imaging techniques and professional matters. Staff (alphabetical order) Ms Jacquie Lee Mr David O’Halloran Dr John Truscott Ms Ann Westmoreland Ongoing Research Current work is unfunded and involves two staff groupings. One, led by Ann Westmoreland is carrying out a systematic review of the impact of assistant practitioners on the delivery of care in the Professions Allied to Medicine. A second grouping, led by Jacquie Lee is carrying out a systematic review into imaging techniques for the early detection of breast cancer. We also currently have 3 full-time (all with scholarships) and 2 part-time PhD students with joint supervision between Healthcare Studies and Medicine. Research completed in the last 2 years 1. S.P.A.R.K.S Maximising growth and mineralisation in preterm infants. £41,778 (1998)

44. Royal Photographic Society - IS Group Homepage The imaging science Group of the Royal Photographic Society (RPS) maintainsan active interest in all aspects of the science and technology of imaging http://www.rps-isg.org/

Group History Evolution Imaging Science ... Go to RPS Site Introduction The Imaging Science Group is one of several Special Interest Groups of the Royal Photographic Society. The Group's fields of interest cover all aspects of the science and technology of imaging - embracing both conventional photography and electronic imaging with image analysis, aerial and satellite technology and much more. The Group channels these interests in three main directions, scientific publications, scientific meetings and education. The Group oversees the production of Imaging Abstracts, published by PIRA International, and plays a major role in the Society's scientific publication, the Imaging Science Journal, as well as keeping members in touch via this website. One or more scientific symposia are arranged each year by the Group at an academic centre such as the Universities of Oxford, Cambridge, and Westminster or in recent years in the cities of Bath and London. Other one-day specialist meetings, sometimes in collaboration with other Learned Societies, and visits to scientific locations are organised. From time to time, meetings of a purely educational nature are also run. The Imaging Science Group adopted this name (the Scientific and Technical Group was originally formed in 1920) in recognition of the need to reflect the Group's broad scope. The Group attracts Members who are professionals in the fields of imaging science and technology (and encourages them to apply for the Society's qualifications in Imaging Science), but also appeals to those with an educational or amateur interest in the science of imaging.

45. Master Of Science Imaging Science Master of Science imaging science Curriculum The online MS in imagingscience curriculum is identical to that of the oncampus version. http://distancelearning.rit.edu/inquire/programs_courses/grad_degree/imaging_sci

Master of Science Imaging Science Program Overview Admission Requirements Curriculum Advising Contact/Department Contact Program Overview This stimulating program is designed for the student holding a bachelor's degree in science or engineering. It will provide important preparation for positions in research in the imaging industry or in the application of various imaging modalities to problems in engineering and science. The master of science curriculum emphasizes a systems approach to the study of imaging science, and with a background in science or engineering, this degree prepares one for positions in research, product development, and management in the imaging industry. The curriculum was developed in collaboration with industrial partners to emphasize skills needed by their scientists, engineers, and managers. Formal course work includes consideration of the physics and chemistry of radiation-sensitive materials and processes, the applications of physical and geometrical optics to electro-optical systems, the mathematical evaluation of image forming systems and the statistics of experimental design and quality control. The online learning program offers the master of science degree curriculum with specified tracks or a customized track can be designed to meet the student's objectives. Admission requirements The online learning program is equivalent to the on-campus program. Admission will be granted to graduates of accredited degree-granting institutions whose undergraduate studies have included at least the following courses in the major areas of study: mathematics through calculus, including differential equations; a full-year calculus-based physics course; a full-year college-level chemistry course, with a laboratory. It is assumed that students can write a computer program using a common language.

46. CISST'2001 - Las Vegas Monte Carlo Resort, Las Vegas, Nevada, USA, 25 28 June 2001. Submission deadline 1 March 2001. http://www.ashland.edu/~iajwa/conferences/2001/CISST2001/cfp.html

The 2001 International Conference on Imaging Science, Systems, and Technology (CISST'2001) June 25 - 28, 2001 Monte Carlo Resort, Las Vegas, Nevada, USA CISST'2001 Call for Papers The 2001 International Conference on Imaging Science, Systems, and Technology (CISST'2001) will be held in Las Vegas, Nevada, June 25 - 28, 2001. The PDPTA'2001 Conference will be held simultaneously (same location and dates) with the following (planned and more will likely be added) international conferences: The 2001 International Conference on Parallel and Distributed Processing Techniques and Applications (PDPTA'2001) The 2001 International Conference on Artificial Intelligence (IC-AI'2001) International Conference on Internet Computing 2001 (IC'2001) The 2001 International Conference on Mathematics and Engineering Techniques in Medicine and Biological Sciences (METMBS'2001) The First International Conference on Engineering of Reconfigurable Systems and Algorithms (ERSA'2001) The 2001 International Symposium on Information Systems and Engineering (ISE'2001) The 2001 International Conference on Communications in Computing (CIC'2001) The 2001 Internation MultiConference will be a major international gathering in year 2001. It is anticipated that this international event will attract about 1500 participants. Attendees will have full access to all five+ conferences.

47. Encyclopedia Of Imaging Science And Technology Toegang voor medewerkers en studenten van deTU/e op basis van IPnummer herkenning. http://www.tue.nl/bib/bestand/weist.html

Toegang voor medewerkers en studenten van de TU/e op basis van IP-nummer herkenning Aanwezig TU/e 2002 electronic version Type Naslagwerk, Encyclopedie Onderwerpen Beeldtechniek Inhoud Online naslagwerk over alle aspecten en deelgebieden van de beeldtechniek, gericht op zowel de theorie als de praktijk. De inhoud van deze online encyclopedie is afgeleid van de gedrukte editie van Wiley uit januari 2002. De inhoud van de gedrukte editie is in deze elektronische versie aangevuld met een grote hoeveelheid beeldmateriaal in kleur. Producent Wiley Voor nadere informatie kunt u contact opnemen met de helpdesk van de bibliotheek. Graag duidelijk uw email- en postadres vermelden.

48. Cassini-Huygens-Spacecraft-Instruments-Imaging Science Subsystem (ISS) The imaging science Subsystem (ISS) onboard the Cassini orbiter is a complex opticalimaging instrument that includes two cameras, one wide and one narrow http://saturn.jpl.nasa.gov/spacecraft/instruments-cassini-iss.cfm

@import url( "../cassini-l2.css" ); Introduction Cassini Orbiter Instruments CAPS CDA ... ISS The Imaging Science Subsystem (ISS) is a Remote Sensing Instrument (think sight) that captures images in visible light, and some in infrared and ultraviolet light. The ISS has a camera that can take a broad, wide-angle picture and a camera that can record small areas in fine detail. Scientists anticipate that Cassini scientists will be able to use ISS to return hundreds of thousands of images of Saturn and its rings and moons. Designed for exploring the entire Saturn system, the Imaging Science Subsystem (ISS) onboard the Cassini-Huygens spacecraft performed well in delivering unusual images back to Earth during its Jupiter flyby ISS-WAC on the Cassini Spacecraft ISS-WAC Instrument ISS-WAC Diagram ISS-NAC on the Cassini Spacecraft ISS-NAC Instrument ISS-NAC Diagram ISS includes two cameras; a Wide Angle Camera (WAC) and a Narrow Angle Camera (NAC). Each uses a sensitive charge-coupled device (CCD) as its detector. Each CCD consists of a 1,024 square array of pixels, 12 microns on a side. The camera's system allows for many data collection modes, including on-chip data compression. Both cameras are fitted with spectral filters that rotate on a wheel to view different bands within the electromagnetic spectrum ranging from 0.2 microns to 1.1 microns. Once at their destination, the cameras will observe Saturn's atmosphere and cloud turbulence, in different spectral wavelengths. In this way, the instrument is able to see both horizontal and vertical layers. The instrument will also study Saturn's rings, the surfaces of the moons orbiting Saturn and possibly discover new moons.

49. CISST'2001 - Las Vegas Monte Carlo Resort, Las Vegas, Nevada, USA, 25 28 June 2001. http://www.ashland.edu/~iajwa/conferences/2001/CISST2001/cisst.html

50. Imaging Science Subsystem (ISS) Optical Remote Sensing imaging science Subsystem(ISS). TL Dr. Carolyn C. Porco. http://saturn.jpl.nasa.gov/cassini/Science/MAPS/ISS.shtml

Optical Remote Sensing: Imaging Science Subsystem (ISS) TL: Dr. Carolyn C. Porco ISS Team Leader: Dr. Carolyn C. Porco Department of Planetary Sciences University of Arizona Tucson, AZ 85721 USA ISS General Description: The Imaging Science Subsystem (ISS) consists of a wide angle camera, with angular resolution of 60 microradians per pixel, and a narrow angle camera, with angular resolution of 6.0 microradians per pixel. The sensors are 1024x1024 CCD arrays. ISS Scientific Objectives: To map the 3-dimensional structure and motions within the Saturn/Titan atmospheres. To study the composition, distribution, and physical properties of clouds and aerosols. To investigate scattering, absorption, and solar heating within the S/T atmospheres. To search for evidence of lightning, aurorae, airglow, and planetary oscillations. To study the gravitational interactions between the rings and Saturn's satellites. To determine the rate and nature of energy and momemtum transfer within the rings. To determine ring thickness and sizes, composition, and physical nature of ring particles.

51. RMIT - Imaging Science And Technology Theory A COSC1401 imaging science And Technology Theory A. Course Name imaging scienceAnd Technology Theory A; Course Code COSC1401; Career Undergraduate; http://www.rmit.edu.au/browse/Academic Programs/Course Guides/Applied Science/A-

52. RMIT - Imaging Science And Technology Theory B COSC1402 imaging science And Technology Theory B. Course Name imaging scienceAnd Technology Theory B; Course Code COSC1402; Career Undergraduate; http://www.rmit.edu.au/browse/Academic Programs/Course Guides/Applied Science/A-

53. First In Class Imaging Science Overview Initiatives imaging science To learn more about the imaging scienceinitiative please contact us, or visit the imaging science http://www2.rit.edu/fic/pub205a0.jsp

54. First In Class Imaging Science People Initiatives imaging science Printable, Ian Gatley, Ph.D. Director, ChesterF. Carlson Center for imaging science 585475-2483 gatley@cis.rit.edu. http://www2.rit.edu/fic/pub205b0.jsp

55. Advanced Computing Technology Applications For SAR Interferometry And Imaging Sc Advanced Computing Technology Applications for SAR Interferometry andimaging science. Principal Investigator David W. Curkendall - JPL. http://pat.jpl.nasa.gov/public/SAR/

SAR Imaging and Interferometry Project ESS Project Advanced Computing Technology Applications for SAR Interferometry and Imaging Science Principal Investigator - David W. Curkendall - JPL A Collaboration of JPL Caltech Scripps Institution of Oceanography UC Santa Barbara NASA COOPERATIVE AGREEMENT NUMBER: RF65/A948 The overall SAR Imaging and Interferometric Science Applications Project is a complex one, being composed of a computational team and three separate science sub-teams. The four organizational units are: A computational challenge Computational Activities The computational team is guided by and is largely responsible for the main computational milestones of the Project: 10, 50, and 100 gigaflops. In addition the objectives of the computational area include the design and implementation of the Scalable SAR Software Suite ( S ), a publicly available set of software for high performance SAR image and interferometry processing (InSAR). Finally, this team is charged with giving the science teams computational support and for developing the visualization techniques used by the Project. The resources The Scalable SAR Parallel Processor (SPP) is a program used to focus raw SAR data into images. It takes RAW SIR-C data and forms images using several steps pre-processing, parameter generation, Correlating, polarization calibration, image generation and image quality assurance.

56. Multivariate Statistics For Imaging Science 0307834 Multivariate Statistics for imaging science. The emphasis is on practicalapplications, and all topics will include case studies from imaging science. http://online.rit.edu/inquire/programs_courses/register/secregform.cfm?CourseID=

57. Welcome To The Laboratory Of Diagnostic Radiology Research At NIH Clinical Cente Clinical research in the imaging sciences within the areas of Magnetic Resonance Imaging, Magnetic Resonance Spectroscopy, Molecular Imaging, Image Processing as well as other areas of imaging sciences. (National Institute of Health) http://www.cc.nih.gov/ldrr/index.html

Vision Statement Mission Statement Strategic Plans Org Chart Vision Statement Mission Statement Strategic Plans Org Chart ... NIH Home Page

58. WileyEurope :: Encyclopedia Of Imaging Science And Technology, 2 Volume Set WileyEurope, Encyclopedia of imaging science andTechnology, 2 Volume Set by Joseph P. Hornak. http://www.wileyeurope.com/cda/product/0,,0471332763|desc|2822,00.html

Shopping Cart My Account Help Contact Us By Keyword By Title By Author By ISBN By ISSN WileyEurope Engineering Communication Technology Encyclopedia of Imaging Science and Technology, 2 Volume Set Related Subjects Optical Materials Satellite Communications Signal Processing General Communication Technology Related Titles Elements of Photonics, Volume II, For Fiber and Integrated Optics (Hardcover) Keigo Iizuka Infrared Technology: Applications to Electro-Optics, Photonic Devices and Sensors (Hardcover) A. R. Jha Handbook of Optical Fibre Sensing Technology (Hardcover) Erfahrungen mit dem Betrieb von Edelgaslasern II (Paperback) Deutsche Forschungsgemeinschaft (DFG) (Editor), Karlheinz Schmidt Kenji Kawano, Tsutomu Kitoh Join an Engineering Mailing List Encyclopedia of Imaging Science and Technology, 2 Volume Set Joseph P. Hornak ISBN: 0-471-33276-3 Hardcover 1584 Pages February 2002 Add to Cart Description Read Excerpt (PDF) Table of Contents Reviews This encyclopedia is the first to offer in-depth coverage of imaging science and technology from a diverse range of applications, techniques and fields of study.

59. Medical Imaging Science MEDICAL imaging science Bruce R Whiting, Ph.D. DEPARTMENT OF RadiologyKeywords computed tomography, medical physics, cochlear http://research.medicine.wustl.edu/ocfr/research.nsf/c517b7f27339413086256797005

60. What Is The Imaging Science Subsystem? The Cassini imaging science Subsystem. The imaging science Subsystem(ISS) is one of the instruments on the Cassini orbiter, managed http://www.maths.qmw.ac.uk/Astronomy/SSD/iss.html

The Cassini Imaging Science Subsystem The Imaging Science Subsystem (ISS) is one of the instruments on the Cassini orbiter, managed as a "facility instrument" by an international team of scientists. ISS will use two CCD cameras to return several hundred thousand pictures of the Saturnian system during the four year tour of the Cassini orbiter between 2004 and 2008. Science Objectives The Pioneer 11 and Voyager 1 and 2 spacecraft observed Saturn in 1979, 1980 and 1981. The images they returned added enormously to our knowledge of Saturn and its rings and satellites. Among their fascinating observations they revealed complicated structure in the rings, discovered satellites that "shepherd" the rings and others that swap orbits. These spacecraft were able to capture relatively few images as they flew by at high speed, spending only a few days swinging past Saturn on their way deeper into space. Cassini, by contrast, will itself become a satellite of Saturn. During a four year "tour" between 2004 and 2008 it will orbit around Saturn acquiring as many as 300,000 images. Using precisely aimed encounters with Saturn's largest moon Titan it will adjust its orbit to perform a thorough exploration of the Saturnian system, viewing it from different positions and paying close visits to many of the moons. This large set of images of the planet, its rings and satellites should allow us to answer many of the questions which were left as open puzzles by the previous missions: questions that often were not even realised to exist before those probes visited Saturn.

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