01307nam a2200301 i 450099100010905970753620020506122131.0981012s1997 it ||| | ita 8878601489b10654847-39ule_instEXGIL139662ExLBiblioteca InterfacoltàitaCentro nazionale per il volontariato533526Solidali con l'arte :secondo rapporto sul volontariato per i beni culturali e artistici in Italia /a cura di Maria Pia Bertolucci, in collaborazione con il Centro nazionale per il volontariato ; Maria Eletta Martini ... [et al.]Torino :Edizioni della Fondazione Giovanni Agnelli,[1997]ix, 158 p. ;21 cm.La società civile in Italia e le sue istituzioni ;3Segue: Appendice.Lavoro sociale volontarioPatrimonio artisticoTutelaBertolucci, Maria PiaMartini, Maria Eletta.b1065484702-04-1428-06-02991000109059707536LE002 Dir. VIII C 2912002000005243le002-E0.00-l- 02020.i1074456328-06-02Solidali con l'arte915709UNISALENTOle00201-01-98ma -itait 0105507nam 2200745Ia 450 991095783530332120200520144314.097866106426499781280642647128064264597800804588850080458882(CKB)1000000000349877(EBL)270166(OCoLC)476002036(SSID)ssj0000145656(PQKBManifestationID)11158180(PQKBTitleCode)TC0000145656(PQKBWorkID)10156940(PQKB)11528496(Au-PeEL)EBL270166(CaPaEBR)ebr10138716(CaONFJC)MIL64264(OCoLC)936844535(PPN)170260712(FR-PaCSA)40000615(MiAaPQ)EBC270166(FRCYB40000615)40000615(EXLCZ)99100000000034987720050511d2005 uy 0engur|n|---|||||txtccrEmbedded media processing /by David Katz and Rick Gentile1st ed.Boston Elsevier/Newnesc20051 online resource (425 p.)Embedded TechnologyIncludes index.9780750679121 0750679123 Front cover; Embedded Media Processing; Copyright page; Table of Contents; Preface; History of This Book; Chapter Overviews; Chapter 1: Embedded Media Processing; Chapter 2: Memory Systems; Chapter 3: Direct Memory Access (DMA); Chapter 4: System Resource Partitioning and Code Optimization; Chapter 5: Basics of Embedded Audio Processing; Chapter 6: Basics of Embedded Video and Image Processing; Chapter 7: Media Processing Frameworks; Chapter 8: Power Management for Embedded Systems; Chapter 9: Application Examples; Acknowledgments; Acronyms; About the AuthorsWhat's on the (Companion website)?Chapter 1: Embedded Media Processing; Why Are You Reading This Book?; So What's All the Excitement About Embedded Multimedia Systems?; A Simplified Look at a Media Processing System; Core Processing; Input/Output Subsystems-Peripheral Interfaces; Subsystem Control; Storage; Connectivity; Data Movement; Memory Subsystem; Laying the Groundwork for an EMP Application; What Kind(s) of Media Am I Dealing With?; What Do I Need to Do With the Data?; Are My System Needs Likely to Change Over Time, or Will This Be a Static System?; Is This a Portable Application?Does my Application Require a Fixed-Point or Floating-Point Device?How Does the Data Get Into and/or Out of the Chip?; How Do I Develop on the Processor?; Do I Need an Operating System?; What Are the Different Ways to Benchmark a Processor?; How Much Am I Willing to Spend?; OK, So What Processor Choices Do I Have?; A Look Inside the Blackfin Processor; System View; Computational Units; Memory Model; DMA; Instruction Flow; Event Handler; Protection of Resources; Programming Model; Power Management; What's Next?; Chapter 2: Memory Systems; Introduction; Memory Spaces; L1 Instruction MemoryL1 Data MemoryCache Overview; What Is Cache?; More Cache Details; External Memory; Synchronous Memory; Asynchronous Memory; What's Next?; Chapter 3: Direct Memory Access; Introduction; DMA Controller Overview; More on the DMA Controller; Programming the DMA Controller; DMA Classifications; Advanced DMA Features; System Performance Tuning; External DMA; What's Next?; Chapter 4: System Resource Partitioning and Code Optimization; Introduction; Event Generation and Handling; System Interrupts; Programming Methodology; Architectural Features for Efficient ProgrammingMultiple Operations per CycleHardware Loop Constructs; Specialized Addressing Modes; Interlocked Instruction Pipelines; Compiler Considerations for Efficient Programming; System and Core Synchronization; Load/Store Synchronization; Ordering; Atomic Operations; Memory Architecture-The Need for Management; Memory Access Tradeoffs; Instruction Memory Management-To Cache or To DMA?; Data Memory Management; System Guidelines for Choosing Between DMA and Cache; Memory Management Unit (MMU); Physics of Data Movement; 1. Grouping Like Transfers to Minimize Memory Bus Turnarounds; Example 4.42. Understanding Core and DMA SDRAM AccessesA key technology enabling fast-paced embedded media processing developments is the high-performance, low-power, small-footprint convergent processor, a specialized device that combines the real-time control of a traditional microcontroller with the signal processing power of a DSP. This practical guide is your one-stop shop for understanding how to implement this cutting-edge technology.You will learn how to:* Choose the proper processor for an application.* Architect your system to avoid problems at the outset.* Manage your data flows and memory accesses so that they lineEmbedded technology series.Signal processingDigital techniquesEmbedded computer systemsSignal processingDigital techniques.Embedded computer systems.004.16Katz David J305860Gentile Rick1797221MiAaPQMiAaPQMiAaPQBOOK9910957835303321Embedded media processing4339349UNINA10974nam 22005173 450 991100844590332120231110224918.09781644902172(electronic bk.)9781644902165(MiAaPQ)EBC30231177(Au-PeEL)EBL30231177(CKB)25301492800041(BIP)086241840(OCoLC)1351198890(Perlego)4733131(EXLCZ)992530149280004120221114d2023 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierEmerging Nanomaterials and Their Impact on Society in the 21st Century1st ed.Millersville :Materials Research Forum LLC,2023.©2023.1 online resource (373 pages)Materials Research Foundations ;v.135Print version: Singh, N. B. Emerging Nanomaterials and Their Impact on Society in the 21st Century Millersville : Materials Research Forum LLC,c2023 9781644902165 Intro -- front-matter -- Table of Contents -- Preface -- 1 -- Nanomaterials: Overview and Historical Perspectives -- 1. Introduction -- 2. Terms associated in nanotechnology -- 3. Historical development of nanotechnology -- 4. Modern era of nanotechnology -- 5. Types of nanomaterials -- 6. Applications of nanomaterials -- 7. Concluding remarks -- References -- 2 -- Nanomaterials in the Lubricant Industry -- 1. Introduction -- 2. Base oils and their classification -- 2.1 Liquid lubricants or lubricating oils -- 2.2 Mechanism of lubrication -- 2.3 Nanoparticles as lubricant additives -- 3. Types of nanoparticles as lubricant additives -- 3.1 Metal oxides -- 3.2 Metals -- 3.3 Metal sulphides -- 3.4 Carbon-based nanomaterials -- 3.5 Boron-based nanomaterials -- 3.6 Nanocomposites -- 4. Factors affecting the lubricating properties of nanoparticles as lubricants -- 4.1 Size of nanoparticle -- 4.2 Shape of nanoparticles -- 4.3 Surface functionalization -- 4.4 Concentration of nanoparticles -- 5. Application fields of nanolubricants -- 6. Roadblocks to full scale use of nanolubricants -- Conclusions -- References -- 3 -- Carbon Nanomaterials and Their Applications -- 1. Introduction -- 2. Properties of nano-carbons -- 3 Fullerenes -- 3.1 Types of fullerenes -- 3.2 Synthesis of fullerenes -- 3.2.1 The arc discharge technique -- 4. The carbon nanotubes (CNTs) -- 4.1 Types of carbon nanotubes (CNTS) -- 4.1.1 Single-walled carbon nanotubes (SWCNTS) -- 4.1.2 Multiple-walled carbon nanotubes (MW-CNTS) -- 5. Synthesis of carbon nanotubes (CNTs) -- 5.1 Arc discharge or plasma-based synthesis technique -- 5.2 Laser ablation technique -- 5.3 Plasma-enhanced chemical vapour deposition (PE-CVD) technique -- 5.4 Thermal synthesis technique -- 5.5 Chemical vapour deposition (CVD) Technique -- 6. Nano-diamonds -- 6.1 Synthesis of nanodiamonds.7. Applications of carbon nanomaterials in water treatment -- 7.1 Fullerenes and water purification -- 7.2 Carbon nanotubes and water purification -- 7.3 Nanoporous activated carbon and water purification -- 7.4 Graphene and water purification -- 8. Carbon nanomaterials in diagnosis and therapy: clinical applications -- 8.1 Biomedical applications of nanodiamonds -- 8.2 Chemo-resistant cancers and nanodiamond drug delivery -- 8.3 Optimized magnetic resonance imaging using nanodiamonds -- 8.4 Carbon nanotubes with functionalized surfaces for improved drug delivery -- 8.5 Tissue engineering and regeneration using functionalized carbon nanotubes -- 8.6 Ex-vivo stem cell development using functionalized carbon nanotubes -- 8.7 Deployment of carbon nanotubes in photoacoustic imaging -- 8.8 Carbon nanofibers for electrochemical sensors and biosensors -- 9. Graphene and graphene oxide in bioanalytical sciences -- 10. Electrochemical sensors based on carbon nanoparticles -- 10.1 Carbon nanotube-based electrochemical sensors -- 10.2 Amperometric transducers made of carbon nanotubes -- 10.3 DNA sensors based on carbon nanotubes -- 10.4 Gas sensors using carbon nanotubes -- 11. Carbon nanoparticles and their applications in the plant system -- 11.1 Seed germination, seedling growth, plant development, and phytotoxicity effects of CNMs -- 11.2 Effects of fullerenes (C60) and fullerols (C60(OH)n) on plants -- 11.3 Effects of graphene on plants -- 11.4 Effects of carbon nanoparticles on plants -- 11.5 Effects of graphene oxide on plants -- 11.6 Effects of mesoporous carbon nanoparticles on plants -- 11.7 Effects of fluorescent carbon dots and carbon nanodots on plants -- Conclusion and future prospects -- References -- 4 -- Functionalized Carbon Nanomaterials: Fabrication, Properties, and Applications -- 1. Introduction -- 2. Historical background.3. Fabrication of functionalized CNMs -- 3.1 Fabrication and functionalization of carbon nanotubes (CNTs) -- 3.2 Fabrication and Functionalization of Expanded grapite (EG) -- 3.3 Fabrication and functionalization of carbon dots (CDs) -- 3.4 Fabrication and functionalization of graphene and graphene oxide (GO) -- 4. Properties of functionalized CNMs -- 4.1 Carbon nanotubes (CNTs) -- 4.2 Expanded graphite (EG) -- 4.3 Carbon dots (CDs) -- 4.4 Graphene and graphene oxide (GO) -- 5. Applications of functionalized CNMs -- 5.1 Carbon nanotubes (CNTs) -- 5.2 Expanded graphite (EG) -- 5.3 Carbon dots (CDs) -- 5.4 Graphene and graphene oxide (GO) -- Conclusions and futuristic approach -- References -- 5 -- Smart Nanomaterials and Their Applications -- 1. Introduction -- 2. A comparison of smart materials and common materials -- 2.1 Advantages and disadvantages of smart nanomaterials -- 2.2 Nanoparticles as sensor -- 3. Types of smart nanomaterials based on stimuli -- 3.1 Physical stimuli-responsive smart nanomaterials -- 3.1.1 Thermoresponsive smart nanomaterials -- 3.1.2 Piezoelectric smart nanomaterials -- 3.1.3 Electrochemical-responsive smart nanomaterials -- 3.1.4 Magneto responsive smart nanomaterials -- 3.1.5 Light responsive smart nanomaterials -- 3.2 Chemical-responsive smart nanomaterials -- 3.2.1 pH-responsive smart nanomaterials -- 3.2.2 Enzyme-responsive smart nanomaterials -- Conclusions -- Acknowledgments -- References -- 6 -- Emerging Nanomaterials in Drug Delivery and Therapy -- 1. Introduction -- 2. Nanomaterials in drug delivery and therapy -- 2.1 Liposomes -- 2.2 Micelles -- 2.3 Lipoprotein-based nanomaterials -- 2.4 Hydrogel -- 2.5 Dendrimers -- 2.6 Carbon nanotubes (CNTs) -- 3. Barriers and challenges -- Conclusions and future perspectives -- References -- 7.Hybrid Nanomaterials: Historical Developments, Classification and Biomedical Applications -- 1. Introduction -- 2. History of hybrid nanomaterials -- 3. Classification of hybrid nanomaterials -- 3.1 First-class hybrid nanomaterials -- 3.2 Second-class hybrid nanomaterials -- 4. Strategies for synthesis of hybrid nanomaterials -- 4.1 In situ formation -- 4.2 Sol-gel process -- 4.3 Electrocrystallization -- 4.4 Hydrothermal method -- 4.5 Wet chemistry approach -- 4.6 Polymerization of organic monomers with preformed inorganic components -- 4.7 Simultaneous incorporation of components -- 5. Applications of hybrid nanomaterials -- 5.1 Mesoporous silica based hybrid nanoparticles -- 5.2 Quantum dot based hybrid nanomaterials -- 5.3 `Nanoscale metal-organic frameworks based hybrid nanomaterials -- 5.4 Iron oxide nanoparticle based hybrid system -- Conclusions -- Acknowledgement -- Competing financial interests -- References -- 8 -- Carbon Nanomaterials for Efficient Perovskite Solar Cells -- 1. Introduction -- 2. Carbon nanotubes (CNTs) in various components of perovskite solar cells -- 2.1 CNT in perovskite layer -- 2.2 Carbon nanotubes in hole transport layer -- Conclusions -- References -- 9 -- Nanoemulsions: Preparation, Properties and Applications -- 1. Introduction -- 2. Preparation of nanoemulsion -- 2.1 High energy method -- 2.1.1 High pressure homogenizer -- 2.1.2 Ultrasonication -- 2.1.3 Microfluidzation method -- 2.2 Low energy methods -- 2.2.1 Phase inversion temperature method (PIT) -- 2.2.2 Phase inversion composition method -- 2.2.3 Spontaneous emulsification -- 2.3 Vapour condensation method: new preparation technique for nanoemulsions -- 3. Properties and characterization of nanoemulsion -- 3.1 Stability -- 3.2 Structure-function property -- 3.3 Rheology -- 3.4 Optical property -- 3.5 Mechanical and barrier properties.3.6 Release property -- 4. Applications of nanoemulsions -- 4.1 Food -- 4.2 Cosmetics -- 4.3 Cell culture technology -- 4.4 Non-toxic disinfectant -- 4.5 Drug delivery -- 4.5.1 Oral delivery -- 4.5.2 Permanent drug delivery -- 4.5.3 Pulmonary drug delivery -- 4.5.4 Intranasal drug delivery -- 4.5.5 Ocular drug delivery system -- 4.5.6 Dermal and transdermal drug delivery system -- 4.5.7 Vaccine delivery -- 4.5.8 Cancer therapy -- 4.5.9 Gene therapy -- 4.6 Nanoemulsion in agriculture -- Conclusions -- References -- 10 -- Effect of Nanomaterials on the Properties of Binding Materials in the Construction Industry -- 1. Introduction -- 2. Different type of binding materials in construction industry -- 2.1 Portland cement and concrete -- 2.2 Geopolymer cement and concrete -- 2.3 LC3 -- 3. Nanomaterials -- 4. Nanoscience and nanotechnology in the building sector -- 5. NMs in cement and concrete -- 5.1 Effect of nano silica -- 5.2 Effect of nano-Fe2O3 -- 5.3 Effect of nano-CaCO3 (NC) -- 5.4 Effect of nano Al2O3 (NA) -- 5.5 Effect of nano ZnO(NZ) -- 5.6 Effect of nano TiO2 (NT) -- 5.7 Effect of carbon nanotubes (CNT) -- 5.8 Effect of graphene based NMs -- 5.9 Effect of nano-clay -- 5.10 Effect of nano-enhanced phase change materials -- 6. Nanomaterials and their impact on the properties of geopolymer cement concrete -- 6.1 Effect of nanosilica (NS) -- 6.2 Effect of nano TiO2 (NT) -- 6.3 Effect of nanoclay -- 6.4 Effect of nanocarbons -- 6.5 Effect of nanoalumina (NA) -- 7. LC3 in presence of nano silica -- Conclusions -- References -- 11 -- Nanoparticles Incorporated Soy Protein Isolate for Emerging Applications in Medical and Biomedical Sectors -- 1. Introduction -- 2. Soy protein based nanocomposites -- 3. Techniques for preparation of nanocomposites based soy protein materials -- 3.1 Wet process -- 3.2 Dry process.4. Different types of SPI-nanocomposites.The book covers the synthesis, classification, characterization, applications and historical background of nanomaterials in various sectors.Materials Research Foundations ScienceSingh N. B1151174Singh N. B.edtMiAaPQMiAaPQMiAaPQ9911008445903321Emerging Nanomaterials and Their Impact on Society in the 21st Century4396393UNINA