01420nam a2200337 i 4500991001559539707536030415s2003 de a b 000 0 eng d354043416Xb12164501-39ule_instDip.to Matematicaeng515.35321AMS 65M60AMS 65M06AMS 68U20LC QA377.L355Langtangen, Hans Petter22965Computational partial differential equations :numerical methods and Diffpack programming /Hans Petter Langtangen2nd ed.Berlin :Springer,c2003xxvi, 855 p. :ill. ;24 cmTexts in computational science and engineering,1611-0994 ;1The 1st ed. was published under the same title as Vol. 2 of the Lecture notes in comnputational science and engineeringIncludes bibliographical references (p. [833]-842) and indexPartial differential equationsNumerical solutionsData processingDiffpack (Computer file).b1216450118-06-1015-04-03991001559539707536LE013 65M LAN11 (2003)12013000138077le013pE64.80-l- 03030.i1250605928-04-03Computational partial differential equations80362UNISALENTOle01315-04-03ma -engde 0100996nmm a2200241 i 4500991002277819707536070323s2000 nyua 000 0 eng db13502852-39ule_instDi.S.Te.B.A.eng571.84422Mitosis and meiosis[electronic resource][Rochester (N. Y.)] :Neo/SCI & Quantum Technology,[2000]1 CD ROM :col. ill. ;23 cmNeo/slide collectionSystems Requirements: Macintosh: Mac 7.1 or higher ; Windows: Windows 95 or higher ; 16 MB RAM ; Quick Time 3.01 or higherMItosisMeiosisNeo/SCI Corporation & Quantum Technolgy.b1350285228-01-1423-03-07991002277819707536LE003 580 NES01.01 (2000)12003000088113le003pE134.15-l- 621620.i1451754118-07-07Mitosis and meiosis83492UNISALENTOle00323-03-07ma -engnyu0002873oam 2200469zu 450 991014677290332120241212215316.09781509097357150909735X(CKB)1000000000022687(SSID)ssj0000453714(PQKBManifestationID)12203627(PQKBTitleCode)TC0000453714(PQKBWorkID)10482501(PQKB)10154394(NjHacI)991000000000022687(EXLCZ)99100000000002268720160829d2005 uy engur|||||||||||txtccr2005 IEEE Nuclear Science Symposium and Medical Imaging Conference[Place of publication not identified]I E E E20051 online resourceBibliographic Level Mode of Issuance: Monograph9780780392212 0780392213 The CMS object oriented Geant4-based program is used to simulate the complete central CMS detector (over 1 million geometrical volumes) and the forward systems such as the Totem telescopes, Castor calorimeter, zero degree calorimeter, Roman pots, and the luminosity monitor. The simulation utilizes the full set of electromagnetic and hadronic physics processes provided by Geant4 and detailed particle tracking in the 4 tesla magnetic field. Electromagnetic shower parameterization can be used instead of full tracking of high-energy electrons and positrons, allowing significant gains in speed without detrimental precision losses. The simulation physics has been validated by comparisons with test beam data and previous simulation results. The system has been in production for almost two years and has delivered over 100 million events for various LHC physics channels. Productions are run on the US and EU grids at a rate of 3-5 million events per month. At the same time, the simulation has evolved to fulfill emerging requirements for new physics simulations, including very large heavy ion events and a variety of SUSY scenarios. The software has also undergone major technical upgrades. The framework and core services have been ported to the new CMS offline software architecture and event data model. In parallel, the program is subjected to ever more stringent quality assurance procedures, including a recently commissioned automated physics validation suite.Imaging systems in medicineCongressesNuclear energyCongressesNuclear physicsCongressesImaging systems in medicineNuclear energyNuclear physics616.0754PQKBPROCEEDING99101467729033212005 IEEE Nuclear Science Symposium and Medical Imaging Conference2539546UNINA