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Format: 1 online resource (244 pages)

ISBN: 9783030886820

Series Statement: Lecture Notes in Intelligent Transportation and Infrastructure Ser.

Additional Edition: Print version: Schirrer, Alexander Energy-Efficient and Semi-Automated Truck Platooning Cham : Springer International Publishing AG,c2022 ISBN 9783030886813

Language: English

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Format: 1 online resource (198 pages)

Edition: 1st ed.

ISBN: 9783031304774

Series Statement: Springer Series in Materials Science Series ; v.333

Note: Intro -- Preface -- Acknowledgements -- Contents -- 1 Introduction -- References -- 2 Review of Theories and a New Classification of Tortuosity Types -- 2.1 Introduction -- 2.1.1 Basic Concept of Tortuosity -- 2.1.2 Basic Challenges -- 2.1.3 Criteria for Classification -- 2.1.4 Content and Structure of This Chapter -- 2.2 Hydraulic Tortuosity -- 2.2.1 Classical Carman-Kozeny Theory -- 2.2.2 From Classical Carman-Kozeny Theory to Modern Characterization of Microstructure Effects -- 2.3 Electrical Tortuosity -- 2.3.1 Indirect Electrical Tortuosity -- 2.3.2 Mixed Electrical Tortuosities -- 2.4 Diffusional Tortuosity -- 2.4.1 Knudsen Number -- 2.4.2 Bulk Diffusion -- 2.4.3 Knudsen Diffusion -- 2.4.4 Limitations to the Concept of Diffusional Tortuosity -- 2.5 Direct Geometric Tortuosity -- 2.5.1 Skeleton and Medial Axis Tortuosity -- 2.5.2 Path Tracking Method (PTM) Tortuosity -- 2.5.3 Geodesic Tortuosity -- 2.5.4 Fast Marching Method (FMM) Tortuosity -- 2.5.5 Percolation Path Tortuosity -- 2.5.6 Pore Centroid Tortuosity -- 2.6 Tortuosity Types: Classification Scheme and Nomenclature -- 2.6.1 Classification Scheme -- 2.6.2 Nomenclature -- 2.7 Summary -- References -- 3 Tortuosity-Porosity Relationships: Review of Empirical Data from Literature -- 3.1 Introduction -- 3.2 Empirical Data for Different Materials and Microstructure Types -- 3.3 Empirical Data for Different Tortuosity Types -- 3.4 Direct Comparison of Tortuosity Types Based on Selected Data Sets -- 3.4.1 Example 1: Indirect Versus Direct Pore Centroid Tortuosity -- 3.4.2 Example 2: Indirect Versus Direct Medial Axis Tortuosity -- 3.4.3 Example 3: Indirect Versus Direct Geodesic Tortuosity -- 3.4.4 Example 4: Indirect Versus Medial Axis Versus Geodesic Tortuosity -- 3.4.5 Example 5: Direct Medial Axis Versus Direct Geodesic Tortuosity. , 3.4.6 Example 6: Mixed Streamline Versus Mixed Volume Averaged Tortuosity -- 3.5 Relative Order of Tortuosity Types -- 3.5.1 Summary of Empirical Data: Global Pattern of Tortuosity Types -- 3.5.2 Interpretation of Different Tortuosity Categories -- 3.6 Tortuosity-Porosity Relationships in Literature -- 3.6.1 Mathematical Expressions for τ-ε Relationships and Their Limitations -- 3.6.2 Mathematical Expressions for τ-ε Relationships and Their Justification -- 3.7 Summary -- References -- 4 Image Based Methodologies, Workflows, and Calculation Approaches for Tortuosity -- 4.1 Introduction -- 4.2 Tomography and 3D Imaging -- 4.2.1 Overview and Introduction to 3D Imaging Methods -- 4.2.2 X-ray Computed Tomography -- 4.2.3 FIB-SEM Tomography and Serial Sectioning -- 4.2.4 Electron Tomography -- 4.2.5 Atom Probe Tomography -- 4.2.6 Correlative Tomography -- 4.3 Available Software Packages for 3D Image Processing and Computation of Tortuosity -- 4.3.1 Methodological Modules -- 4.3.2 Different Types of SW Packages -- 4.4 From Tomography Raw Data to Segmented 3D Microstructures: Step by Step Example of Qualitative Image Processing -- 4.5 Calculation Approaches for Tortuosity -- 4.5.1 Calculation Approaches and SW for Direct Geometric Tortuosities (τdir_geom) -- 4.5.2 Calculation Approaches and SW for Indirect Physics-Based Tortuosities (τindir_phys) -- 4.5.3 Calculation Approaches for Mixed Tortuosities -- 4.6 Pore Scale Modeling for Tortuosity Characterization: Examples from Literature -- 4.6.1 Examples of Pore Scale Modeling in Geoscience -- 4.6.2 Examples of Pore Scale Modeling for Energy and Electrochemistry Applications -- 4.7 Stochastic Microstructure Modeling -- 4.7.1 Stochastic Modeling for Digital Materials Design (DMD) of Electrochemical Devices -- 4.7.2 Stochastic Modeling for Digital Rock Physics and Virtual Materials Testing of Porous Media. , 4.8 Summary -- References -- 5 Towards a Quantitative Understanding of Microstructure-Property Relationships -- 5.1 Introduction -- 5.2 Quantitative Micro-Macro Relationships for the Prediction of Conductivity and Diffusivity -- 5.3 Quantitative Micro-Macro Relationships for the Prediction of Permeability -- 5.3.1 Bundle of Tubes Model -- 5.3.2 Sphere Packing Model -- 5.3.3 Determination of Characteristic Length and M-factor by Laboratory Experiments -- 5.3.4 Determination of Characteristic Length and M-factor by 3D Image Analysis -- 5.3.5 Determination of Characteristic Length and M-factor by Virtual Materials Testing -- 5.4 Summary -- References -- 6 Summary and Conclusions.

Additional Edition: Print version: Holzer, Lorenz Tortuosity and Microstructure Effects in Porous Media Cham : Springer International Publishing AG,c2023 ISBN 9783031304767

Language: English

Keywords: Electronic books. ; Electronic books.

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Format: 1 online resource (223 pages)

Edition: 1st ed.

ISBN: 9783030172077

Series Statement: Springer Topics in Signal Processing Series ; v.19

Note: Intro -- Preface -- Acknowledgements -- Outline -- Contents -- 1 XY, MS, and First-Order Ambisonics -- 1.1 Blumlein Pair: XY Recording and Playback -- 1.2 MS Recording and Playback -- 1.3 First-Order Ambisonics (FOA) -- 1.3.1 2D First-Order Ambisonic Recording and Playback -- 1.3.2 3D First-Order Ambisonic Recording and Playback -- 1.4 Practical Free-Software Examples -- 1.4.1 Pd with Iemmatrix, Iemlib, and Zexy -- 1.4.2 Ambix VST Plugins -- 1.5 Motivation of Higher-Order Ambisonics -- References -- 2 Auditory Events of Multi-loudspeaker Playback -- 2.1 Loudness -- 2.2 Direction -- 2.2.1 Time Differences on Frontal, Horizontal Loudspeaker Pair -- 2.2.2 Level Differences on Frontal, Horizontal Loudspeaker Pair -- 2.2.3 Level Differences on Horizontally Surrounding Pairs -- 2.2.4 Level Differences on Frontal, Horizontal to Vertical Pairs -- 2.2.5 Vector Models for Horizontal Loudspeaker Pairs -- 2.2.6 Level Differences on Frontal Loudspeaker Triangles -- 2.2.7 Level Differences on Frontal Loudspeaker Rectangles -- 2.2.8 Vector Model for More than 2 Loudspeakers -- 2.2.9 Vector Model for Off-Center Listening Positions -- 2.3 Width -- 2.3.1 Model of the Perceived Width -- 2.4 Coloration -- 2.5 Open Listening Experiment Data -- References -- 3 Amplitude Panning Using Vector Bases -- 3.1 Vector-Base Amplitude Panning (VBAP) -- 3.2 Multiple-Direction Amplitude Panning (MDAP) -- 3.3 Challenges in 3D Triangulation: Imaginary Loudspeaker Insertion and Downmix -- 3.4 Practical Free-Software Examples -- 3.4.1 VBAP/MDAP Object for Pd -- 3.4.2 SPARTA Panner Plugin -- References -- 4 Ambisonic Amplitude Panning and Decoding in Higher Orders -- 4.1 Direction Spread in First-Order 2D Ambisonics -- 4.2 Higher-Order Polynomials and Harmonics -- 4.3 Angular/Directional Harmonics in 2D and 3D -- 4.4 Panning with Circular Harmonics in 2D. , 4.5 Ambisonics Encoding and Optimal Decoding in 2D -- 4.6 Listening Experiments on 2D Ambisonics -- 4.7 Panning with Spherical Harmonics in 3D -- 4.8 Ambisonic Encoding and Optimal Decoding in 3D -- 4.9 Ambisonic Decoding to Loudspeakers -- 4.9.1 Sampling Ambisonic Decoder (SAD) -- 4.9.2 Mode Matching Decoder (MAD) -- 4.9.3 Energy Preservation on Optimal Layouts -- 4.9.4 Loudness Deficiencies on Sub-optimal Layouts -- 4.9.5 Energy-Preserving Ambisonic Decoder (EPAD) -- 4.9.6 All-Round Ambisonic Decoding (AllRAD) -- 4.9.7 EPAD and AllRAD on Sub-optimal Layouts -- 4.9.8 Decoding to Hemispherical 3D Loudspeaker Layouts -- 4.10 Practical Studio/Sound Reinforcement Application Examples -- 4.11 Ambisonic Decoding to Headphones -- 4.11.1 High-Frequency Time-Aligned Binaural Decoding (TAC) -- 4.11.2 Magnitude Least Squares (MagLS) -- 4.11.3 Diffuse-Field Covariance Constraint -- 4.12 Practical Free-Software Examples -- 4.12.1 Pd and Circular/Spherical Harmonics -- 4.12.2 Ambix Encoder, IEM MultiEncoder, and IEM AllRADecoder -- 4.12.3 Reaper, IEM RoomEncoder, and IEM BinauralDecoder -- References -- 5 Signal Flow and Effects in Ambisonic Productions -- 5.1 Embedding of Channel-Based, Spot-Microphone, and First-Order Recordings -- 5.2 Frequency-Independent Ambisonic Effects -- 5.2.1 Mirror -- 5.2.2 3D Rotation -- 5.2.3 Directional Level Modification/Windowing -- 5.2.4 Warping -- 5.3 Parametric Equalization -- 5.4 Dynamic Processing/Compression -- 5.5 Widening (Distance/Diffuseness/Early Lateral Reflections) -- 5.6 Feedback Delay Networks for Diffuse Reverberation -- 5.7 Reverberation by Measured Room Impulse Responses and Spatial Decomposition Method in Ambisonics -- 5.8 Resolution Enhancement: DirAC, HARPEX, COMPASS -- 5.9 Practical Free-Software Examples -- 5.9.1 IEM, ambix, and mcfx Plug-In Suites -- 5.9.2 Aalto SPARTA -- 5.9.3 Røde -- References. , 6 Higher-Order Ambisonic Microphones and the Wave Equation (Linear, Lossless) -- 6.1 Equation of Compression -- 6.2 Equation of Motion -- 6.3 Wave Equation -- 6.3.1 Elementary Inhomogeneous Solution: Green's Function (Free Field) -- 6.4 Basis Solutions in Spherical Coordinates -- 6.5 Scattering by Rigid Higher-Order Microphone Surface -- 6.6 Higher-Order Microphone Array Encoding -- 6.7 Discrete Sound Pressure Samples in Spherical Harmonics -- 6.8 Regularizing Filter Bank for Radial Filters -- 6.9 Loudness-Normalized Sub-band Side-Lobe Suppression -- 6.10 Influence of Gain Matching, Noise, Side-Lobe Suppression -- 6.11 Practical Free-Software Examples -- 6.11.1 Eigenmike Em32 Encoding Using Mcfx and IEM Plug-In Suites -- 6.11.2 SPARTA Array2SH -- References -- 7 Compact Spherical Loudspeaker Arrays -- 7.1 Auditory Events of Ambisonically Controlled Directivity -- 7.1.1 Perceived Distance -- 7.1.2 Perceived Direction -- 7.2 First-Order Compact Loudspeaker Arrays and Cubes -- 7.3 Higher-Order Compact Spherical Loudspeaker Arrays and IKO -- 7.3.1 Directivity Control -- 7.3.2 Control System and Verification Based on Measurements -- 7.4 Auditory Objects of the IKO -- 7.4.1 Static Auditory Objects -- 7.4.2 Moving Auditory Objects -- 7.5 Practical Free-Software Examples -- 7.5.1 IEM Room Encoder and Directivity Shaper -- 7.5.2 IEM Cubes 5.1 Player and Surround with Depth -- 7.5.3 IKO -- References -- Appendix -- A.1 Harmonic Functions -- A.2 Laplacian in Orthogonal Coordinates -- A.3 Laplacian in Spherical Coordinates -- A.3.1 The Radial Part -- A.3.2 The Azimuthal Part -- A.3.3 The Zenithal Part -- A.3.4 Azimuthal Solution in 2D and 3D -- A.3.5 Towards Spherical Harmonics (3D) -- A.3.6 Zenithal Solution: Associated Legendre Differential Equation -- A.3.7 Spherical Harmonics -- A.4 Encoding to SH and Decoding to SH. , A.5 Covariance Constraint for Binaural Ambisonic Decoding -- A.6 Physics of the Helmholtz Equation -- A.6.1 Adiabatic Compression -- A.6.2 Potential and Kinetic Sound Energies, Intensity, Diffuseness -- A.6.3 Green's Function in 3 Cartesian Dimensions -- A.6.4 Radial Solution of the Helmholtz Equation -- A.6.5 Green's Function in Spherical Solutions, Angular Distributions, Plane Waves -- A.7 Sine and Tangent Law -- References.

Additional Edition: Print version: Zotter, Franz Ambisonics Cham : Springer International Publishing AG,c2019 ISBN 9783030172060

Language: English

Keywords: Electronic books.

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URL: http://www.vlebooks.com/vleweb/product/openreader?id=none&isbn=9783030172077

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Format: 1 Online-Ressource (242 Seiten)

Edition: 1. Auflage

ISBN: 9783966050630

Series Statement: Fachwissen

Content: Selbstbestimmtes Wohnen als Reformziel des BTHG 2020 werden die Leistungen der Eingliederungshilfe in den zweiten Teil des Rehabilitationsgesetzes für Menschen mit Behinderung SGB IX überführt. Getrennt von den existenzsichernden Leistungen werden sie dann als Assistenzleistungen für das selbstbestimmte und eigenverantwortliche Wohnen sowie in besonderen Wohnformen erbracht. Eine Jahrzehnte alte Vision der Sozialpsychiatrie erhält damit die Chance der Umsetzung. Expertinnen und Experten beschreiben praxisnah die neuen Rahmenbedingungen, die aktuelle Forschungslage und die alltäglichen Herausforderungen, sodass Leitungskräfte und Mitarbeitende von Leistungsanbietern und Kostenträgern mit der Lektüre dieses Buches für die wichtigste Reformstufe des BTHG gut aufgestellt sind. Quelle: Verlagsangabe

Note: "Für die 3. Reformstufe des BTHG" - Zusatz auf dem Cover , "Aus diesem Grund haben wir uns entschieden, alle Beiträge aus dem Vorgängerbuch [...] zu bündeln und nur diese aktualisiert und z.t. auch stark überarbeitet in der nun vorliegenden kompakteren Form neu herauszugeben." - Vorwort

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 3-96605-057-9

Additional Edition: ISBN 978-3-96605-057-9

Former: Vorangegangen ist Selbstbestimmtes Wohnen

Language: German

Keywords: Deutschland ; Betreutes Wohnen ; Psychische Störung ; Ambulante psychiatrische Versorgung ; Stationäre psychiatrische Versorgung ; Deutschland Bundesteilhabegesetz ; Betreutes Wohnen ; Persönliche Assistenz ; Selbstbestimmung ; Teilhabe ; Aufsatzsammlung ; Electronic books.

URL: https://ebookcentral.proquest.com/lib/th-brandenburg/detail.action?docID=6847072

Author information: Konrad, Michael 1955-

Author information: Rosemann, Matthias 1957-