01062nam0 22002651i 450 SUN004349420060405120000.088-15-02403-420060405d1989 |0itac50 baitaIT|||| |||||Dantela poetica della conversioneJohn FrecceroBolognaIl mulino1989358 p.22 cm.001SUN00435022001 Collezione di testi e di studi. Linguistica e critica letteraria210 BolognaIl mulino.BolognaSUNL000003Freccero, JohnSUNV035362200470Il mulinoSUNV000011650ITSOL20181109RICASUN0043494UFFICIO DI BIBLIOTECA DEL DIPARTIMENTO DI LETTERE E BENI CULTURALI07 CONS Zb Dante 752 07 1624 UFFICIO DI BIBLIOTECA DEL DIPARTIMENTO DI LETTERE E BENI CULTURALIIT-CE01031624CONS Zb Dante 752caDante136480UNICAMPANIA03815nam 22006495 450 99646595240331620200706023033.03-642-40392-110.1007/978-3-642-40392-7(CKB)3710000000015920(SSID)ssj0000988197(PQKBManifestationID)11534672(PQKBTitleCode)TC0000988197(PQKBWorkID)10949344(PQKB)10191954(DE-He213)978-3-642-40392-7(MiAaPQ)EBC3093147(PPN)172429439(EXLCZ)99371000000001592020130820d2013 u| 0engurnn|008mamaatxtccrLightweight Cryptography for Security and Privacy[electronic resource] 2nd International Workshop, LightSec 2013, Gebze, Turkey, May 6-7, 2013, Revised Selected Papers /edited by Gildas Avoine, Orhun Kara1st ed. 2013.Berlin, Heidelberg :Springer Berlin Heidelberg :Imprint: Springer,2013.1 online resource (X, 143 p. 24 illus.) Security and Cryptology ;8162Bibliographic Level Mode of Issuance: Monograph3-642-40391-3 Efficient Implementations and designs -- A Lightweight ATmega-based Application-Specific Instruction-Set Processor for Elliptic Curve Cryptography -- ITUbee: A Software Oriented Lightweight Block Cipher -- Block Cipher Cryptanalysis -- Related-Key Slide Attacks on Block Ciphers with Secret Components -- Differential Fault Attack on the PRINCE Block Cipher -- Multidimensional Meet-in-the-Middle Attacks on Reduced-Round TWINE-128 -- Wireless Sensor Networks -- An Implementation of the Hash-Chain Signature Scheme for Wireless Sensor Networks -- An adaptive security architecture for location privacy sensitive sensor network applications -- Cryptographic Protocols -- Secure & Lightweight Distance-Bounding -- Cryptanalysis and Improvement of a Provably Secure RFID Ownership Transfer Protocol -- An Efficient and Private RFID Authentication Protocol Supporting Ownership Transfer.This book constitutes the proceedings of the 2th International Workshop on Lightweight Cryptography for Security and Privacy, LightSec 2013, held in Gebze, Turkey, during May 6-7, 2013. The 10 full papers presented together with 3 invited talks were carefully reviewed and selected from 27 submissions. The papers are grouped in topical sections on efficient Implementations and designs, block cipher cryptanalysis, wireless sensor networks, and cryptographic protocols.Security and Cryptology ;8162Data encryption (Computer science)Computer securityComputer communication systemsCryptologyhttps://scigraph.springernature.com/ontologies/product-market-codes/I28020Systems and Data Securityhttps://scigraph.springernature.com/ontologies/product-market-codes/I28060Computer Communication Networkshttps://scigraph.springernature.com/ontologies/product-market-codes/I13022Data encryption (Computer science).Computer security.Computer communication systems.Cryptology.Systems and Data Security.Computer Communication Networks.005.8Avoine Gildasedthttp://id.loc.gov/vocabulary/relators/edtKara Orhunedthttp://id.loc.gov/vocabulary/relators/edtMiAaPQMiAaPQMiAaPQBOOK996465952403316Lightweight Cryptography for Security and Privacy2829839UNISA04635nam 2200613Ia 450 991083051100332120180612234820.01-282-48269-697866124826943-527-62950-53-527-62951-3(CKB)2550000000007396(EBL)485695(SSID)ssj0000363958(PQKBManifestationID)11278417(PQKBTitleCode)TC0000363958(PQKBWorkID)10394279(PQKB)10853206(MiAaPQ)EBC485695(OCoLC)663465086(EXLCZ)99255000000000739620100329d2010 uy 0engur|n|---|||||txtccrOptically pumped atoms[electronic resource] alkali-metal vapors for application /William Happer, Yuan-Yu Jau, and Thad WalkerWeinheim Wiley-VCH20101 online resource (248 p.)Description based upon print version of record.3-527-40707-3 Optically Pumped Atoms; Contents; Preface; Index to Codes; 1 Introduction; 2 Alkali-Metal Atoms; 2.1 Electronic Energies; 2.2 Valence-Electron Wave Functions; 2.3 Hyperfine Structure; 3 Wave Functions and Schrödinger Space; 3.1 Uncoupled States; 3.1.1 Kronecker Products; 3.1.2 Angular Momentum Matrices; 3.2 Energy States; 3.3 Zero-Field States; 4 Density Matrix and Liouville Space; 4.1 Purity and Entropy; 4.2 Ground State, Excited State, and Optical Coherence; 4.3 Column-Vector and Row-Vector Transforms; 4.3.1 Column-Vector Transforms; 4.3.2 Row-Vector Transforms; 4.3.3 Expectation Values5.2.6 Amplitude D5.2.7 Energy Basis; 5.3 Spontaneous Emission; 5.4 Electric Dipole Interaction; 5.5 Rotating Coordinate System; 5.6 Net Evolution; 5.6.1 The Amagat Unit of Density; 5.6.2 Normalization; 5.6.3 Notation and Coding; 5.7 Optical Bloch Equations; 5.8 Liouville Space; 5.8.1 Transients; 5.8.2 Steady State; 5.8.3 Steady State Versus Detuning; 6 Quasi-Steady-State Optical Pumping; 6.1 Ground-State Evolution; 6.2 Excited-State Evolution; 6.3 Collisions; 6.4 Saturation; 6.5 Identities; 6.6 Net Evolution; 6.7 Negligible Stimulated Emission; 6.8 High-Pressure Pumping; 6.8.1 Liouville Space6.9 Spectral Width of Pumping Light6.9.1 Gaussian Spectral Profiles; 6.9.2 Plasma Dispersion Function; 6.10 Doppler Broadening; 7 Modulation; 7.1 Magnetic Resonance; 7.2 Modulated Light; 7.2.1 High Pressure; 7.2.2 Lower Pressure; 7.2.3 Modulated Optical Pumping Matrices; 7.3 Secular Approximation; 7.4 Attenuation of Modulated Coherence in Passingthrough the Excited State; 7.5 Examples; 7.5.1 Isolated Magnetic Resonances; 7.5.2 Zeeman Magnetic Resonances; 7.5.3 Push-Pull Pumping; 8 Light Propagation; 8.1 Induced Electric Dipole Moment; 8.2 Absorption Cross Section; 8.3 Small Magnetic Fields8.4 Evolution of a Beam in Space and Time8.5 First-Order Propagation Equation; 8.6 Propagation of Weak Probe Light; 8.7 Faraday Rotation; 8.8 Specific Absorption; 8.9 Fluorescent Light; 9 Radiation Forces; 9.1 Mean Force; 9.2 Forces from Monochromatic Light; 9.3 Forces in Magneto-Optical Traps; 9.3.1 Repump Lasers; 9.4 Pointing Probability; 9.5 Momentum Space; 9.6 Evolution in Spin-Momentum Space; 9.7 Liouville Space; 9.8 Compactification; 9.8.1 Compactified pq Space; 9.8.2 Compactification within a Tile; 9.9 Displays; 9.9.1 Momentum-Space Displays; 9.9.2 Position-Space Displays9.10 Momentum DiffusionCovering the most important knowledge on optical pumping of atoms, this ready reference is backed by numerous examples of modelling computation for optical pumped systems. The authors show for the first time that modern scientific computing software makes it practical to analyze the full, multilevel system of optically pumped atoms. To make the discussion less abstract, the authors have illustrated key points with sections of MATLAB codes. To make most effective use of contemporary mathematical software, it is especially useful to analyze optical pumping situations in the Liouville spaOptical pumpingChemistryOptical pumping.Chemistry.539.7UH 7600rvkHapper William27144Jau Yuan-Yu1628716Walker Thad1628717MiAaPQMiAaPQMiAaPQBOOK9910830511003321Optically pumped atoms3965991UNINA