LEADER 00803nam0-22003011i-450 001 990001731070403321 005 20190529131342.0 035 $a000173107 035 $aFED01000173107 035 $a(Aleph)000173107FED01 035 $a000173107 100 $a20030910d1938----km-y0itay50------ba 101 0 $afre 200 1 $a<>culture du Quinquina$epossibilites au Congo Belge$fA. Ringoet 210 $aGembloux$cDuculot$d1938 215 $a41 p.$d26 cm 610 0 $aCongo Belga 610 0 $aPiante medicinali 610 0 $aChina 676 $a633.38 700 1$aRingoet,$bA.$074972 801 0$aIT$bUNINA$gRICA$2UNIMARC 901 $aLG 912 $a990001731070403321 952 $a60 OP. 37/2$b33819$fFAGBC 959 $aFAGBC 996 $aCulture du Quinquina$9365198 997 $aUNINA LEADER 00976nam0 22002891i 450 001 RML0302838 005 20231121125745.0 010 $a1841127051 100 $a20121121d2006 ||||0itac50 ba 101 | $aeng 102 $agb 181 1$6z01$ai $bxxxe 182 1$6z01$an 200 1 $aKnowledge management$fCarl Frappaolo 210 $aChichester $cCapstone Publishing $d2006 215 $a136 p.$d18 cm. 606 $aGestione delle informazioni$2FIR$3RMLC362423$9I 676 $a658.4038$9$v21 700 1$aFrappaolo$b, Carl$3RMLV195352$01340165 801 3$aIT$bIT-01$c20121121 850 $aIT-FR0099 899 $aBiblioteca Area Ingegneristica$bFR0099 912 $aRML0302838 950 0$aBiblioteca Area Ingegneristica$d 54DMS 658.4 FRA$e 54VM 0000729705 VM barcode:BAIN004031. - Inventario:2299MVM$fB $h20080130$i20121204 977 $a 54 996 $aKnowledge management$93061805 997 $aUNICAS LEADER 01051nam0 22002893i 450 001 TO01860878 005 20231121125846.0 010 $a9788884071880 100 $a20171211d2012 ||||0itac50 ba 101 | $aita 102 $ait 181 1$6z01$ai $bxxxe 182 1$6z01$an 200 1 $a˜L'œarte, nonostante tutto$ericerche sulla musica, la pittura e la poesia: tra estetica ed ermeneutica$fAnnalisa Caputo 210 $aRoma$cCVS$d[2012] 215 $a173 p.$cill.$d23 cm 606 $aEstetica$2FIR$3RMLC119958$9I 676 $a111.85$9Filosofia. Proprietà classiche dell'essere. Bellezza.$v22 700 1$aCaputo$b, Annalisa$3CFIV177941$0174869 801 3$aIT$bIT-01$c20171211 850 $aIT-FR0017 899 $aBiblioteca umanistica Giorgio Aprea$bFR0017 912 $aTO01860878 950 0$aBiblioteca umanistica Giorgio Aprea$d 52DCB Cap.Art.$e 52SBA0000232725 VMB RS $fA $h20171211$i20171211 977 $a 52 996 $aArte, nonostante tutto$93638914 997 $aUNICAS LEADER 09066nam 2200541 450 001 9910816370303321 005 20231110213241.0 010 $a1-118-94980-3 010 $a1-118-94979-X 010 $a1-118-94981-1 035 $a(CKB)4330000000007631 035 $a(MiAaPQ)EBC6607709 035 $a(Au-PeEL)EBL6607709 035 $a(OCoLC)1251441246 035 $a(PPN)258541725 035 $a(EXLCZ)994330000000007631 100 $a20220118d2021 uy 0 101 0 $aeng 135 $aurcnu|||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aIntroduction to flight testing /$fJames W. Gregory, Tianshu Liu 205 $aFirst edition. 210 1$aHoboken, New Jersey :$cWiley,$d[2021] 210 4$d©2021 215 $a1 online resource (355 pages) 225 1 $aAerospace 311 1 $a1-118-94982-X 320 $aIncludes bibliographical references and index. 327 $aCover -- Title Page -- Copyright -- Contents -- About the Authors -- Series Preface -- Preface -- Acknowledgements -- About the Companion Website -- Chapter 1 Introduction -- 1.1 Case Study: Supersonic Flight in the Bell XS?1 -- 1.2 Types of Flight Testing -- 1.2.1 Scientific Research -- 1.2.2 Experimental Flight Test -- 1.2.3 Developmental Test and Evaluation -- 1.2.4 Operational Test and Evaluation -- 1.2.5 Airworthiness Certification -- 1.3 Objectives and Organization of this Book -- References -- Chapter 2 The Flight Environment: Standard Atmosphere -- 2.1 Earth's Atmosphere -- 2.2 Standard Atmosphere Model -- 2.2.1 Hydrostatics -- 2.2.2 Gravitational Acceleration and Altitude Definitions -- 2.2.3 Temperature -- 2.2.4 Viscosity -- 2.2.5 Pressure and Density -- 2.2.6 Operationalizing the Standard Atmosphere -- 2.2.7 Comparison with Experimental Data -- 2.3 Altitudes Used in Aviation -- References -- Chapter 3 Aircraft and Flight Test Instrumentation -- 3.1 Traditional Cockpit Instruments -- 3.1.1 Gyroscopic?Based Instruments -- 3.1.2 Pressure?Based Instruments -- 3.1.3 Outside Air Temperature -- 3.1.4 Other Instrumentation -- 3.2 Glass Cockpit Instruments -- 3.3 Flight Test Instrumentation -- 3.3.1 Global Navigation Satellite System -- 3.3.2 Accelerometers -- 3.3.3 Gyroscopes -- 3.3.4 Magnetometers -- 3.3.5 Barometer -- 3.3.6 Fusion of Sensor Data Streams -- 3.4 Summary -- References -- Chapter 4 Data Acquisition and Analysis -- 4.1 Temporal and Spectral Analysis -- 4.2 Filtering -- 4.3 Digital Sampling: Bit Depth Resolution and Sample Rate -- 4.4 Aliasing -- 4.5 Flight Testing Example -- 4.6 Summary -- References -- Chapter 5 Uncertainty Analysis -- 5.1 Error Theory -- 5.1.1 Types of Errors -- 5.1.2 Statistics of Random Error -- 5.1.3 Sensitivity Analysis and Uncertainty Propagation -- 5.1.4 Overall Uncertainty Estimate. 327 $a5.1.5 Chauvenet's Criterion for Outliers -- 5.1.6 Monte Carlo Simulation -- 5.2 Basic Error Sources in Flight Testing -- 5.2.1 Uncertainty of Flight Test Instrumentation -- 5.2.2 Example: Uncertainty in Density (Traditional Approach) -- 5.2.3 Example: Uncertainty in True Airspeed (Monte Carlo Approach) -- References -- Chapter 6 Flight Test Planning -- 6.1 Flight Test Process -- 6.2 Risk Management -- 6.3 Case Study: Accept No Unnecessary Risk -- 6.4 Individual Flight Planning -- 6.4.1 Flight Area and Airspace -- 6.4.2 Weather and NOTAMs -- 6.4.3 Weight and Balance -- 6.4.4 Airplane Pre?Flight -- 6.5 Conclusion -- References -- Chapter 7 Drag Polar Measurement in Level Flight -- 7.1 Theory -- 7.1.1 Drag Polar and Power Required for Level Flight -- 7.1.2 The PIW-VIW Method -- 7.1.3 Internal Combustion Engine Performance Additional details are available in an online supplement, "Basic Performance Prediction of Internal Combustion Engines." -- 7.1.4 Propeller Performance -- 7.2 Flight Testing Procedures -- 7.3 Flight Test Example: Cirrus SR20 -- References -- Chapter 8 Airspeed Calibration -- 8.1 Theory -- 8.1.1 True Airspeed -- 8.1.2 Equivalent Airspeed -- 8.1.3 Calibrated Airspeed -- 8.1.4 Indicated Airspeed -- 8.1.5 Summary -- 8.2 Measurement Errors -- 8.2.1 Instrument Error -- 8.2.2 System Lag -- 8.2.3 Position Error -- 8.3 Airspeed Calibration Methods -- 8.3.1 Boom?Mounted Probes -- 8.3.2 Trailing Devices and Pacer Aircraft -- 8.3.3 Ground?Based Methods -- 8.3.4 Global Positioning System Method -- 8.4 Flight Testing Procedures -- 8.5 Flight Test Example: Cirrus SR20 -- References -- Chapter 9 Climb Performance and Level Acceleration to Measure Excess Power -- 9.1 Theory -- 9.1.1 Steady Climbs -- 9.1.2 Energy Methods -- 9.2 Flight Testing Procedures -- 9.2.1 Direct Measurement of Rate of Climb -- 9.2.2 Measurement of Level Acceleration. 327 $a9.3 Data Analysis -- 9.4 Flight Test Example: Cirrus SR20 -- References -- Chapter 10 Glide Speed and Distance -- 10.1 Theory -- 10.1.1 Drag Polar -- 10.1.2 Gliding Flight -- 10.1.3 Glide Hodograph -- 10.1.4 Best Glide Condition -- 10.2 Flight Testing Procedures -- 10.3 Data Analysis -- 10.4 Flight Test Example: Cirrus SR20 -- References -- Chapter 11 Takeoff and Landing -- 11.1 Theory -- 11.1.1 Takeoff Ground Roll -- 11.1.2 Landing Ground Roll -- 11.1.3 Rotation Distance -- 11.1.4 Transition Distance -- 11.1.5 Climb Distance -- 11.1.6 Total Takeoff and Landing Distances -- 11.1.7 Simple Estimations -- 11.2 Measurement Methods -- 11.3 Flight Testing Procedures -- 11.3.1 Standard Flight Procedures -- 11.3.2 Flight Test Procedures -- 11.3.3 Data Acquisition -- 11.3.4 Data Analysis -- 11.4 Flight Test Example: Cessna R182 -- References -- Chapter 12 Stall Speed -- 12.1 Theory -- 12.1.1 Viscous Boundary Layers -- 12.1.2 Flow Separation -- 12.1.3 Two?Dimensional Stall Characteristics -- 12.1.4 Three?Dimensional Stall Characteristics -- 12.1.5 Stall Control -- 12.1.6 Stall Prediction -- 12.2 Flight Testing Procedures -- 12.2.1 Flight Characteristics -- 12.2.2 Data Acquisition -- 12.3 Data Analysis -- 12.4 Flight Test Example: Cirrus SR20 -- References -- Chapter 13 Turning Flight -- 13.1 Theory -- 13.2 Flight Testing Procedures -- 13.2.1 Airworthiness Certification -- 13.2.2 Educational Flight Testing -- 13.2.3 Piloting -- 13.2.4 Instrumentation and Data Recording -- 13.3 Flight Test Example: Diamond DA40 -- References -- Chapter 14 Longitudinal Stability -- 14.1 Static Longitudinal Stability -- 14.1.1 Theory -- 14.1.2 Trim Condition -- 14.1.3 Flight Testing Procedures -- 14.1.4 Flight Test Example: Cirrus SR20 -- 14.2 Dynamic Longitudinal Stability -- 14.2.1 Theory -- 14.2.2 Flight Testing Procedures -- 14.2.3 Flight Test Example: Cirrus SR20. 327 $aReferences -- Chapter 15 Lateral?Directional Stability -- 15.1 Static Lateral?Directional Stability -- 15.1.1 Theory -- 15.1.2 Directional Stability -- 15.1.3 Lateral Stability -- 15.1.4 Flight Testing Procedures -- 15.1.5 Flight Testing Example: Cirrus SR20 -- 15.2 Dynamic Lateral?Directional Stability -- 15.2.1 Theory -- 15.2.2 Flight Testing Procedures -- 15.2.3 Flight Test Example: Cirrus SR20 -- Nomenclature -- Acronyms and Abbreviations -- References -- Chapter 16 UAV Flight Testing1 -- 16.1 Overview of Unmanned Aircraft -- 16.2 UAV Design Principles and Features -- 16.2.1 Types of Airframes -- 16.2.2 UAV System Architecture -- 16.2.3 Electric Propulsion -- 16.2.4 Command and Control (C2) Link -- 16.2.5 Autonomy -- 16.3 Flight Regulations -- 16.4 Flight Testing Principles -- 16.4.1 Air Data Instrumentation -- 16.4.2 UAV Flight Test Planning -- 16.4.3 Piloting for UAV Flight Testing -- 16.5 Flight Testing Examples with the Peregrine UAS -- 16.5.1 Overview of the Peregrine UAS -- 16.5.2 Propulsion System Characterization -- 16.5.3 Specific Excess Power: Level Acceleration and Rate of Climb -- 16.5.4 Glide Flight Tests -- 16.6 Flight Testing Examples with the Avanti UAS -- 16.6.1 Overview of the Avanti UAS -- 16.6.2 Coast?Down Testing for the Drag Polar -- 16.6.3 Radio Range Testing -- 16.6.4 Assessment of Autonomous System Performance -- 16.7 Conclusion -- References -- Appendix A Standard Atmosphere Tables -- Appendix B Useful Constants and Unit Conversion Factors -- Reference -- Appendix C Stability and Control Derivatives for a Notional GA Aircraft -- Reference -- Index -- EULA. 330 $aIntroduction to Flight Testing provides a concise introduction to the basic flight testing methods employed on general aviation aircraft and unmanned aerial vehicles for courses in aeronautical engineering. There is particular emphasis on the use of modern on-board instruments and inexpensive, off-the-shelf portable devices that make flight testing accessible to nearly any student. 410 0$aAerospace 606 $aAirplanes$xFlight testing$vTextbooks 615 0$aAirplanes$xFlight testing 676 $a629.13453 700 $aGregory$b James W.$0272448 702 $aLiu$b T$g(Tianshu), 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910816370303321 996 $aIntroduction to flight testing$93990683 997 $aUNINA LEADER 05629nam 22006495 450 001 9910136611303321 005 20200702124950.0 024 7 $a10.1007/978-3-319-45150-3 035 $a(CKB)3710000000902972 035 $a(EBL)4717299 035 $a(DE-He213)978-3-319-45150-3 035 $a(MiAaPQ)EBC4717299 035 $a(PPN)196324661 035 $a(EXLCZ)993710000000902972 100 $a20161012d2017 u| 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aSynchronization Control for Large-Scale Network Systems /$fby Yuanqing Wu, Renquan Lu, Hongye Su, Peng Shi, Zheng-Guang Wu 205 $a1st ed. 2017. 210 1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2017. 215 $a1 online resource (241 p.) 225 1 $aStudies in Systems, Decision and Control,$x2198-4182 ;$v76 300 $aIncludes index. 311 $a3-319-45149-9 311 $a3-319-45150-2 327 $aPreface; Contents; Symbols and Acronyms; 1 Introduction; 1.1 Synchronization of LSNSs; 1.2 Algebraic Graph Theory; 1.2.1 Time-Varying Graph; 1.2.2 Time-Invariant Graph; 1.2.3 Hierarchical Decomposition; 1.3 Book Organization; 1.4 Some Lemmas; References; LSNSs with Sampled-Data Communication; 2 Sampled-Data Control with Actuators Saturation; 2.1 Introduction; 2.2 Preliminaries; 2.3 Main Results; 2.4 Numerical Example; 2.5 Conclusion; References; 3 Sampled-Data Control with Constant Delay; 3.1 Introduction; 3.2 Preliminaries; 3.3 Sampled-Data Control 327 $a3.4 Sampled-Data Control with Constant Delay3.5 Numerical Example; 3.6 Conclusion; References; 4 Sampled-Data Control with Time-Varying Coupling Delay; 4.1 Introduction; 4.2 Preliminaries; 4.3 Main Results; 4.4 Numerical Examples; 4.5 Conclusion; References; 5 An Input-Based Triggering Approach to LSNSs; 5.1 Introduction; 5.2 Problem Formulation and Preliminaries; 5.2.1 System Models; 5.2.2 Communication Protocols; 5.2.3 Event Triggered Predictors and Controllers; 5.3 Stability and Inter-Event Intervals; 5.3.1 Time-Dependent Threshold; 5.3.2 Time-Independent Threshold 327 $a5.4 Extension to Directed Graphs5.5 Simulation Examples; 5.5.1 Undirected Graph; 5.5.2 Directed Graphs; 5.6 Conclusion; References; LSNSs with Non-Identical Nodes; 6 Robust Output Synchronization via Internal Model Principle; 6.1 Introduction; 6.2 Problem Statement; 6.3 Consensus of Reference Generators; 6.4 Output Regulation Theory; 6.4.1 Internal Model Principle; 6.4.2 Robust Internal Model Principle; 6.5 Numerical Example; 6.6 Conclusion; References; 7 Output Synchronization via Hierarchical Decomposition; 7.1 Introduction; 7.2 Problem Formulation 327 $a8 Synchronization of LSNSs via Static Output Feedback Control8.1 Introduction; 8.2 Problem Formulation and Preliminaries; 8.3 Stability and Control Synthesis; 8.4 Hinfty Performance and Control Synthesis; 8.5 Simulation Example; 8.6 Conclusion; References; 9 Robust Output Regulation via Hinfty Approach; 9.1 Introduction; 9.2 Problem Formulation; 9.3 Identical Reference Generator; 9.4 Robust Regulation via Hinfty Methods; 9.5 Numerical Example; 9.6 Conclusion; References; 10 Adaptive Output Synchronization with Uncertain Leader; 10.1 Introduction; 10.2 Problem Formulation; 10.3 Main Results 327 $a10.3.1 Stage 1: Output Synchronization Among Uncertain Leader and Adaptive Reference Generators 330 $aThis book provides recent advances in analysis and synthesis of Large-scale network systems (LSNSs) with sampled-data communication and non-identical nodes. In its first chapter of the book presents an introduction to Synchronization of LSNSs and Algebraic Graph Theory as well as an overview of recent developments of LSNSs with sampled data control or output regulation control. The main text of the book is organized into two main parts - Part I: LSNSs with sampled-data communication and Part II: LSNSs with non-identical nodes. This monograph provides up-to-date advances and some recent developments in the analysis and synthesis issues for LSNSs with sampled-data communication and non-identical nodes. It describes the constructions of the adaptive reference generators in the first stage and the robust regulators in the second stage. Examples are presented to show the effectiveness of the proposed design techniques. 410 0$aStudies in Systems, Decision and Control,$x2198-4182 ;$v76 606 $aAutomatic control 606 $aVibration 606 $aDynamics 606 $aDynamics 606 $aControl and Systems Theory$3https://scigraph.springernature.com/ontologies/product-market-codes/T19010 606 $aVibration, Dynamical Systems, Control$3https://scigraph.springernature.com/ontologies/product-market-codes/T15036 615 0$aAutomatic control. 615 0$aVibration. 615 0$aDynamics. 615 0$aDynamics. 615 14$aControl and Systems Theory. 615 24$aVibration, Dynamical Systems, Control. 676 $a620 700 $aWu$b Yuanqing$4aut$4http://id.loc.gov/vocabulary/relators/aut$0941830 702 $aLu$b Renquan$4aut$4http://id.loc.gov/vocabulary/relators/aut 702 $aSu$b Hongye$4aut$4http://id.loc.gov/vocabulary/relators/aut 702 $aShi$b Peng$4aut$4http://id.loc.gov/vocabulary/relators/aut 702 $aWu$b Zheng-Guang$4aut$4http://id.loc.gov/vocabulary/relators/aut 906 $aBOOK 912 $a9910136611303321 996 $aSynchronization Control for Large-Scale Network Systems$92124974 997 $aUNINA