LEADER 00809nam0-22003011i-450- 001 990003346500403321 005 20001010 010 $a0-1402-1492-5 035 $a000334650 035 $aFED01000334650 035 $a(Aleph)000334650FED01 035 $a000334650 100 $a20001010d--------km-y0itay50------ba 101 0 $aita 105 $ay-------001yy 200 1 $aDRAMA FROM IBSEN TO BRECHT 210 $aHARMONDSWORTH$cPENGUIN BOOKS$d1978 610 0 $aLetteratura Inglese ( Drammatica ) 676 $a822.3 700 1$aWilliams,$bRaymond$f<1921-1988>$0309364 801 0$aIT$bUNINA$gRICA$2UNIMARC 901 $aBK 912 $a990003346500403321 952 $a822 WIL$bLINGUE 99$fDECLI 959 $aDECLI 996 $aDrama from Ibsen to Brecht$9146522 997 $aUNINA DB $aING01 LEADER 00704nam 2200253 450 001 9910423956503321 005 20201130122023.0 010 $a9788820390426 100 $a20201130d2020----u y0engy50 ba 101 0 $aita 102 $aIT 105 0 $a 00 200 1 $aNel nome del padre e del figlio$fErmanno Bencivenga 210 $aMilano$cHoepli$d2020 215 $a150 p.$d22 cm 225 $aInvasioni$v1 610 0 $aPadri$aRapporti con i figli 676 $a306.8742$v22$zita 700 1$aBencivenga,$bErmanno$f<1950- >$044782 912 $a9910423956503321 952 $a306.8742 BEN 1$b7514$fbfs 959 $aBFS 996 $aNel nome del padre e del figlio$91762043 997 $aUNINA LEADER 03664nam 2200673Ia 450 001 9910453857003321 005 20200520144314.0 010 $a1-281-78415-X 010 $a9786611784157 010 $a0-8264-3072-4 035 $a(CKB)1000000000541644 035 $a(EBL)436627 035 $a(OCoLC)276295980 035 $a(SSID)ssj0000195842 035 $a(PQKBManifestationID)11157127 035 $a(PQKBTitleCode)TC0000195842 035 $a(PQKBWorkID)10141215 035 $a(PQKB)11165118 035 $a(MiAaPQ)EBC436627 035 $a(Au-PeEL)EBL436627 035 $a(CaPaEBR)ebr10250902 035 $a(CaONFJC)MIL178415 035 $a(OCoLC)893334187 035 $a(EXLCZ)991000000000541644 100 $a20050727e20051996 fy 0 101 0 $aeng 135 $aurcn||||||||| 181 $ctxt 182 $cc 183 $acr 200 00$aMaking histories in museums$b[electronic resource] /$fedited by Gaynor Kavanagh 210 $aLondon ;$aNew York $cContinuum$d[2005] 215 $a1 online resource (302 p.) 225 1 $aContinuum collection 300 $aOriginally published: London: Leicester University Press, 1996. 311 $a0-8264-7926-X 320 $aIncludes bibliographical references and index. 327 $aContents; Illustrations; Contributors; Preface; Acknowledgements; 1 Making Histories, Making Memories; 2 Time Heals: Making History in Medical Museums; 3 Making Rural Histories; 4 Why Not Invent the Past We Display in Museums?; 5 Trying To Be an Honest Woman: Making Women's Histories; 6 Making Family Histories in the National Portrait Gallery, Australia; 7 African Americans, History and Museums: Preserving African American History in the Public Arena; 8 Making Histories of African Caribbeans 327 $a9 Cleaning Up the Coal-Face and Doing Out the Kitchen: The Interpretation of Work and Workers in Wales 10 Hard Men, Hard Facts and Heavy Metal: Making Histories of Technology; 11 Making City Histories; 12 Travelers' Boots, Body-Moulding, Rubber Fetish Clothes: Making Histories of Sub-cultures; 13 Making Histories of Wars; 14 Making Histories of Sexuality; 15 Making Culturally Diverse Histories; 16 Making Histories of Religion; 17 Making Histories from Archaeology; 18 History and Folklore; 19 Making the History Curriculum 327 $a20 Shadows and Sacred Geography: First Nations History-Making from an Alberta Perspective 21 Making Children's Histories; Index 330 $aThis exciting new series recognizes the tremendous potential of museum-based histories and the ways in which they can engage people with ideas about the past. People encounter and use museums on many different levels - personal, social and intellectual - and access meanings that best fit their agendas. Histories in museums can stimulate the imagination, provoke discussion and increase our ability to question what we know. From this it can be deduced that history in museums is as much about the present as it is about the past; as much about how we feel as about what we know; as much about who 410 0$aContinuum collection. 606 $aMuseums$xHistory 606 $aHistorical museums$xHistory 606 $aMuseum techniques$xHistory 608 $aElectronic books. 615 0$aMuseums$xHistory. 615 0$aHistorical museums$xHistory. 615 0$aMuseum techniques$xHistory. 676 $a069.09 676 $a069/.09 701 $aKavanagh$b Gaynor$0962735 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910453857003321 996 $aMaking histories in museums$92234566 997 $aUNINA LEADER 10509nam 22004333 450 001 9910865289703321 005 20240626081653.0 010 $a9783031500541$b(electronic bk.) 010 $z9783031500534 035 $a(MiAaPQ)EBC31466777 035 $a(Au-PeEL)EBL31466777 035 $a(CKB)32274067600041 035 $a(EXLCZ)9932274067600041 100 $a20240614d2024 uy 0 101 0 $aeng 135 $aurcnu|||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aIntroduction to Unsteady Aerodynamics and Dynamic Aeroelasticity 205 $a1st ed. 210 1$aCham :$cSpringer,$d2024. 210 4$dİ2024. 215 $a1 online resource (804 pages) 311 08$aPrint version: Demasi, Luciano Introduction to Unsteady Aerodynamics and Dynamic Aeroelasticity Cham : Springer,c2024 9783031500534 327 $aIntro -- Endorsement -- Preface -- Contents -- 1 Introduction: Learning Aeroelasticity -- 1.1 What Is Aeroelasticity? -- 1.1.1 Intuitive Concepts on Aeroelasticity -- 1.2 What Is New in This Book -- 1.3 Learning/Teaching Aeroelasticity -- 1.4 How Could Aeroelasticity Be Presented/Learned -- 1.5 Education of Engineers -- Part I Review of Mathematical Concepts -- 2 Finite-Part Integrals -- 2.1 An Introduction to Cauchy Principal Value -- 2.2 A More General Example of Cauchy Principal Value Integrals -- 2.2.1 A Sufficient Condition to Assure the Existence of Cauchy Principal Value Integral -- 2.3 An Introduction to Hadamard Finite-Part Integrals -- 2.4 Case of Hadamard Finite-Part Integrals Obtained by Using Cauchy Principal Value Integrals -- 2.5 Hadamard Finite-Part Surface Integrals -- 2.6 Competency Questions -- 3 Convolution and Duhamel Integrals -- 3.1 Review of Convolution Integrals for Linear Systems -- 3.1.1 Example of Convolution Integral -- 3.2 Review on Duhamel Integral (Step Response) -- 3.2.1 Relationship Between Step and Impulse Responses -- 3.3 Competency Questions -- 4 Laplace and Fourier Transforms -- 4.1 Fourier Transforms -- 4.2 Laplace Transforms -- 4.3 Competency Questions -- 5 Review of the Least Square Method -- 5.1 Definition of the Problem -- 5.2 Definition and Minimization of the Error -- 5.3 Competency Questions -- 6 Vector Identities Used in Aerodynamics -- 6.1 Vectors -- 6.2 Second-Order Tensors -- 6.3 Summation Convention -- 6.4 Kronecker's Delta and Permutation Symbol -- 6.5 Applications of Kronecker's Delta and Permutation Symbols -- 6.5.1 Scalar Product -- 6.5.2 Cross Product -- 6.5.3 -? Identity -- 6.5.4 Double Cross Product -- 6.6 Dyadic Product -- 6.6.1 Definition -- 6.6.2 Properties -- 6.7 Del Operator -- 6.8 A Vectorial Relationship Used in the Definition of Potential Flows. 327 $a6.9 A Vectorial Relationship Used in Definition of Vorticity -- 6.10 A Vectorial Relationship Used in Biot and Savart Law -- 6.11 First-Order Substantial Derivative Operator -- 6.11.1 Physical Interpretation -- 6.12 Competency Questions -- Part II Fundamental Equations of Aerodynamics -- 7 Reynolds Transport Theorem, Isentropic, Continuity, and Momentum Equations -- 7.1 Introduction -- 7.2 General Concepts -- 7.2.1 Boundary Layer, Wake, and Generation of Vortices -- 7.3 Leibniz Rule of Differentiation of Integrals -- 7.3.1 Leibniz Rule for the 3D Case -- 7.4 Continuity Equation Written by Using Reynolds Transport Theorem -- 7.4.1 Continuity Equation Expressed in Terms of Substantial Derivative -- 7.5 Momentum Equation Written by Using Reynolds Transport Theorem -- 7.5.1 Simplification of the Momentum Equation -- 7.5.2 Momentum Equation Expressed in Terms of Substantial Derivative -- 7.6 State Equation for Air -- 7.7 The Isentropic Relationship -- 7.8 Mach Number and Speed of Sound -- 7.8.1 Explicit Expression of the Speed of Sound -- 7.9 Competency Questions -- 8 Vorticity and Kelvin's Circulation Theorem -- 8.1 Angular Velocity and Vorticity -- 8.1.1 Divergence of Vorticity -- 8.1.2 Vortex Line, Surface, and Tube -- 8.1.3 Strength of a Vortex Tube -- 8.1.4 Kelvin's Circulation Theorem -- 8.1.5 Consequence of Kelvin's Circulation Theorem on Vortex Dynamics -- 8.2 Competency Questions -- Part III Velocity and Acceleration Potentials -- 9 Velocity and Acceleration Potentials -- 9.1 Introduction -- 9.2 Definition of Velocity Potential -- 9.3 Generalized Bernoulli Equation -- 9.4 The Lord Kelvin Equation -- 9.5 The Coefficient of Pressure Written in Terms of Velocity Potential -- 9.6 Speed of Sound Expressed in Terms of Velocity Potential -- 9.7 Derivation of the Velocity Potential Equation (Compressible Case). 327 $a9.8 Derivation of the Velocity Potential Equation (Incompressible Case) -- 9.9 Velocity Potential and Wake Discontinuities -- 9.10 The Acceleration Potential -- 9.10.1 Velocity Potential Equation Expressed in Terms of Acceleration Potential -- 9.11 Competency Questions -- 10 The Biot-Savart Law for Incompressible Fluids -- 10.1 Introduction -- 10.2 Demonstration of the Biot-Savart Law -- 10.3 The Biot-Savart Law Applied to an Infinite Straight Filament -- 10.4 The Biot-Savart Law Applied to a Semi-infinite Straight Filament -- 10.5 The Biot-Savart Law Applied to a Finite Portion of a Straight Filament -- 10.6 Semi-infinite Straight Filament: The Numerical Formula -- 10.7 The Case of Point Exactly on the Vortex -- 10.8 Vortex Filament and Laplace's Equation -- 10.9 Competency Questions -- Part IV Fluid-Structure Boundary Condition -- 11 The Fluid-Structure Boundary Condition -- 11.1 Introduction -- 11.2 Derivation of the Dynamic Aeroelastic Boundary Condition -- 11.3 Boundary Condition for a Wing Surface Referred to the x-y Plane -- 11.4 Boundary Condition for a Wing Surface Referred to a Cylindrical Surface -- 11.5 Derivation of the Steady Aeroelastic Boundary Condition -- 11.6 Competency Questions -- Part V Aerodynamic Force for the Steady Incompressible Ideal Flow -- 12 The Aerodynamic Force for the Steady Incompressible Ideal Flow -- 12.1 Determination of the Aerodynamic Force (Incompressible Steady Flow) -- 12.2 Competency Questions -- Part VI Theory of Small Perturbations -- 13 Small Perturbation Theory -- 13.1 Introduction -- 13.2 Modeling of the Wake, Thickness, and Camber -- 13.3 Small Perturbation Velocity Potential -- 13.4 Linearized First and Second Substantial Derivatives -- 13.5 Linearized Pressure -- 13.6 Linearized Coefficient of Pressure -- 13.7 Linearized Velocity Potential Equation. 327 $a13.8 Linearized Velocity Potential Equation Written in the Fourier Domain -- 13.9 Linearized Velocity Potential and Wake Discontinuities -- 13.10 Linearized Aeroelastic Boundary Condition -- 13.10.1 Boundary Condition for a Wing Surface Referred to the x-y Plane -- 13.10.2 Boundary Condition for a Wing Surface Referred to a Cylindrical Surface -- 13.10.3 Perturbation from a Reference Equilibrium Configuration -- 13.11 Competency Questions -- 14 Small Perturbation Acceleration Potential -- 14.1 Linearization Process -- 14.2 Differential Equation the Small Perturbation Acceleration Potential Needs to Satisfy -- 14.3 Behavior of the Small Perturbation Acceleration Potential Across the Wake -- 14.4 The Integral Relationship Between Small Perturbation Velocity and Acceleration Potentials -- 14.5 Competency Questions -- Part VII Fundamental Solutions of the Small Perturbation Velocity Potential Equation -- 15 Compressible Fluid at Rest -- 15.1 Introduction -- 15.2 Explicit Form of the Partial Differential Equation and Boundary Conditions -- 15.3 Strategy to Solve the Partial Differential Equations and Introduce the Doublet Lattice Method -- 15.4 The Source as Fundamental Solution for the Fluid at Rest -- 15.4.1 Definition of the Source/Sink (Steady Case) -- 15.4.2 Source with Intensity Kept Constant After Activation -- 15.4.3 Source with Intensity Changing with Time -- 15.5 Competency Questions -- 16 Compressible Fluid in Motion -- 16.1 Introduction -- 16.2 The Source as Fundamental Solution for the Fluid in Motion -- 16.2.1 Steady Case -- 16.2.2 Unsteady Case: Spherical Source Activated at Time Zero -- 16.3 Small Perturbation Velocity Potential of a Spherical Source Pulsating with Generic Law -- 16.4 Small Perturbation Velocity Potential of a Spherical Source at a Generic Position Pulsating with Generic Law. 327 $a16.5 Small Perturbation Velocity Potential of a Spherical Source at a Generic Position Pulsating with Harmonic Law -- 16.6 Potential Induced by a Doublet (Harmonic Motion) Positioned at the Origin -- 16.7 Potential Induced by a Doublet (Harmonic Motion) Positioned at the Origin: An Alternative Approach -- 16.8 Potential Induced by a Doublet (Harmonic Motion) Positioned at a Generic Position -- 16.9 Harmonic Motion: Small Perturbation Velocity Potential of a Doublet at a Generic Position: Case of Doublets' Axes Contained in the y-z Plane -- 16.10 Competency Questions -- Part VIII Fundamental Solutions of the Small Perturbation Acceleration Potential Equation -- 17 Compressible Fluid in Motion: The Doublet Solution -- 17.1 The Formal Equality Between Small Perturbation Velocity and Acceleration Potentials -- 17.2 Solutions of Small Perturbation Acceleration Potential for the Case of Harmonic Motion -- 17.2.1 Relationship Between Pressure Jump and Doublet Amplitudes -- 17.3 Competency Questions -- Part IX Steady State Aerodynamics -- 18 Theoretical Aerodynamic Modeling of Wings -- 18.1 Introduction -- 18.2 Steady Incompressible Ideal Flow and Modeling of Wings -- 18.3 Steady Incompressible Ideal Flow and Modeling of Infinite Wings -- 18.3.1 Kutta-Joukowsky Theorem -- 18.3.2 Finding the Vortex Distribution -- 18.3.3 The Case of Flat Plate and Its Implications on the Doublet Lattice Method -- 18.4 Competency Questions -- 19 Steady Incompressible Ideal Flow and Modeling of Finite Wings -- 19.1 Introduction -- 19.2 The Vortex Lattice Method -- 19.3 Formulation of the Problem with the Vortex Lattice Method -- 19.4 Implementation of the Vortex Lattice Method -- 19.4.1 Imposition of the Symmetry Conditions -- 19.5 Vortex Lattice Formulation in Terms of Pressure -- 19.6 Prandtl-Glauert Compressibility Correction. 327 $a19.7 The Matrix of Aerodynamic Influence Coefficients for the Compressible Case. 676 $a629.132362 700 $aDemasi$b Luciano$01742175 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 912 $a9910865289703321 996 $aIntroduction to Unsteady Aerodynamics and Dynamic Aeroelasticity$94168771 997 $aUNINA