Golden, CO : , : National Renewable Energy Laboratory, , 2020

1 online resource (1 page) : color illustrations

NREL/PO ; ; 5400-71474

Motor vehicles - Design and construction

Transportation - Databases

Inglese

Presented at the 2018 Vehicle Technologies Annual Merit Review, 18-21 June 2018, Arlington, Virginia.

"June 20, 2018."

Chichester, West Sussex, United Kingdom : , : IEEE Press, Wiley, , [2016]

[Piscataqay, New Jersey] : , : IEEE Xplore, , [2016]

1-118-93618-3

1-118-93616-7

1-118-93617-5

1 online resource (858 p.)

Wiley - IEEE

SteerMichael Bernard

621.38132

Microwave integrated circuits

Strip transmission lines

Inglese

Description based upon print version of record.

Includes bibliographical references at the end of each chapters and index.

-- Preface xxiii -- Acknowledgements xxv -- 1 Introduction to Design Using Microstrip and Planar Lines 1 -- 1.1 Introduction 1 -- 1.2 Origins of Microstrip 2 -- 1.3 RF and Microwave Modules 4 -- 1.4 Interconnections on RF and Microwave Integrated Circuits 13 -- 1.5 High-speed Digital Interconnections 15 -- 1.6 Summary 18 -- References 18 -- 2 Fundamentals of Signal Transmission on Interconnects 19 -- 2.1 Introduction 19 -- 2.2 Transmission Lines and Interconnects 19 -- 2.3 Interconnects as Part of a Packaging Hierarchy 20 -- 2.4 The Physical Basis of Interconnects 21 -- 2.5 The Physics, a Guided Wave 23 -- 2.6 When an Interconnect Should be Treated as a Transmission Line 32 -- 2.7 The Concept of RF Transmission Lines 34 -- 2.8 Primary Transmission Line Constants 34 -- 2.9 Secondary Constants for Transmission Lines 35 -- 2.10 Transmission Line Impedances 37 -- 2.11 Reflection 38 -- 2.12 Multiple Conductors 41 -- 2.13 Return Currents 44 -- 2.14 Modeling of Interconnects 47 -- 2.15 Summary 49 -- References 50 -- 3 Microwave Network Analysis 51 -- 3.1 Introduction 51 -- 3.2 Two-port Networks 51 -- 3.3 Scattering Parameter Theory 55 -- 3.4 Signal-flow Graph Techniques and S Parameters 70 -- 3.5 Summary 74 -- References 74 -- 4

Transmission Line Theory 76 -- 4.1 Introduction 76 -- 4.2 Transmission Line Theory 76 -- 4.3 Chain (ABCD) Parameters for a Uniform Length of Loss-free Transmission Line 81 -- 4.4 Change in Reference Plane 82 -- 4.5 Working With a Complex Characteristic Impedance 83 -- 4.6 Summary 87 -- References 88 -- 5 Planar Interconnect Technologies 89 -- 5.1 Introductory Remarks 89 -- 5.2 Microwave Frequencies and Applications 89 -- 5.3 Transmission Line Structures 91 -- 5.4 Substrates for Planar Transmission Lines 98 -- 5.5 Thin-film Modules 102 -- 5.6 Thick-film Modules 104 -- 5.7 Monolithic Technology 105 -- 5.8 Printed Circuit Boards 108 -- 5.9 Multichip Modules 111 -- 5.10 Summary 116 -- References 117 -- 6 Microstrip Design at Low Frequencies 120 -- 6.1 The Microstrip Design Problem 120.

6.2 The Quasi-TEM Mode of Propagation 122 -- 6.3 Static-TEM Parameters 124 -- 6.4 Effective Permittivity and Characteristic Impedance of Microstrip 127 -- 6.5 Filling Factor 132 -- 6.6 Approximate Graphically Based Synthesis 134 -- 6.7 Formulas for Accurate Static-TEM Design Calculations 137 -- 6.8 Electromagnetic Analysis-based Techniques 139 -- 6.9 A Worked Example of Static-TEM Synthesis 140 -- 6.10 Microstrip on a Dielectrically Anisotropic Substrate 141 -- 6.11 Microstrip and Magnetic Materials 146 -- 6.12 Effects of Finite Strip Thickness, Metallic Enclosure, and Manufacturing -- Tolerances 147 -- 6.13 Pulse Propagation along Microstrip Lines 151 -- 6.14 Recommendations Relating to the Static-TEM Approaches 152 -- 6.15 Summary 154 -- References 155 -- 7 Microstrip at High Frequencies 157 -- 7.1 Introduction 157 -- 7.2 Frequency-dependent Effects 157 -- 7.3 Approximate Calculations Accounting for Dispersion 169 -- 7.4 Accurate Design Formulas 173 -- 7.5 Effects due to Ferrite and to Dielectrically Anisotropic Substrates 182 -- 7.6 Field Solutions 183 -- 7.7 Frequency Dependence of Microstrip Characteristic Impedance 186 -- 7.8 Multimoding and Limitations on Operating Frequency 190 -- 7.9 Design Recommendations 194 -- 7.10 Summary 196 -- References 196 -- 8 Loss and Power-dependent Effects in Microstrip 200 -- 8.1 Introduction 200 -- 8.2 Q Factor as a Measure of Loss 200 -- 8.3 Power Losses and Parasitic Effects 208 -- 8.4 Superconducting Microstrip Lines 216 -- 8.5 Power-handling Capabilities 219 -- 8.6 Passive Intermodulation Distortion 221 -- 8.7 Summary 224 -- References 224 -- 9 Discontinuities in Microstrip 227 -- 9.1 Introduction 227 -- 9.2 The Main Discontinuities 228 -- 9.3 Bends in Microstrip 236 -- 9.3.1 The Right-angled Bend or “Corner” 236 -- 9.3.2 Mitered or “Matched” Microstrip Bends, Compensation Techniques 238 -- 9.4 Step Changes in Width (Impedance Step) 241 -- 9.4.1 The Symmetrical Microstrip Step 241 -- 9.4.2 The Asymmetrical Step in Microstrip 243.

9.5 The Narrow Transverse Slit 243 -- 9.6 Microstrip Junctions 245 -- 9.7 Recommendations for the Calculation of Discontinuities 261 -- 9.8 Summary 266 -- References 266 -- 10 Parallel-coupled Microstrip Lines 268 -- 10.1 Introduction 268 -- 10.2 Coupled Transmission Line Theory 269 -- 10.3 Formulas for Characteristic Impedance of Coupled Lines 278 -- 10.4 Semi-empirical Analysis Formulas as a Design Aid 290 -- 10.5 An Approximate Synthesis Technique 301 -- 10.6 Summary 304 -- References 304 -- 11 Applications of Parallel-coupled Microstrip Lines 306 -- 11.1 Introduction 306 -- 11.2 Directional Couplers 306 -- 11.3 Design Example: Design of a 10 dB Microstrip Coupler 308 -- 11.4 Frequency- and Length-Dependent Characteristics of Directional Couplers 310 -- 11.5 Special Coupler Designs with Improved Performance 315 -- 11.6 Thickness Effects, Power Losses, and Fabrication Tolerances 329 -- 11.7 Choice of

Structure and Design Recommendations 331 -- 11.8 Summary 336 -- References 337 -- 12 Microstrip Passive Elements 339 -- 12.1 Introduction 339 -- 12.2 Lumped Elements 339 -- 12.3 Terminations and Attenuators 343 -- 12.4 Microstrip Stubs 345 -- 12.5 Hybrids and Couplers 348 -- 12.6 Power Combiners and Dividers 355 -- 12.7 Baluns 357 -- 12.8 Integrated Components 359 -- 12.9 Summary 365 -- References 365 -- 13 Stripline Design 369 -- 13.1 Introduction 369 -- 13.2 Symmetrical Stripline 370 -- 13.3 Asymmetrical Stripline 373 -- 13.4 Suspended Stripline 375 -- 13.5 Coupled Stripline 375 -- 13.6 Double-sided Stripline 379 -- 13.7 Discontinuities 380 -- 13.8 Design Recommendations 381 -- 13.9 Summary 382 -- References 382 -- 14 CPW Design Fundamentals 384 -- 14.1 Introduction to Properties of Coplanar Waveguide 384 -- 14.2 Modeling CPWs 389 -- 14.3 Formulas for Accurate Calculations 391 -- 14.4 Loss Mechanisms 393 -- 14.5 Dispersion 397 -- 14.6 Discontinuities 408 -- 14.7 Circuit Elements 421 -- 14.8 Variants on the Basic CPW Structure 430 -- 14.9 Summary 439 -- References 439.

15 Slotline 443 -- 15.1 Introduction 443 -- 15.2 Basic Concept and Structure 444 -- 15.3 Operating Principles and Modes 444 -- 15.4 Propagation and Dispersion Characteristics 447 -- 15.5 Evaluation of Guide Wavelength and Characteristic Impedance 451 -- 15.6 Losses 453 -- 15.7 End-effects: Open Circuits and Short Circuits 455 -- 15.8 Summary 463 -- References 463 -- 16 Slotline Applications 465 -- 16.1 Introduction 465 -- 16.2 Comparators and Couplers 465 -- 16.3 Filter Applications 472 -- 16.4 Magic T 474 -- 16.5 The Marchand Balun 477 -- 16.6 Phase Shifters 480 -- 16.7 Isolators and Circulators 481 -- 16.8 A Double-sided, Balanced Microwave Circuit 486 -- 16.9 Summary 486 -- References 486 -- 17 Transitions 488 -- 17.1 Introduction 488 -- 17.2 Coaxial-to-microstrip Transitions 488 -- 17.3 Waveguide-to-microstrip Transitions 490 -- 17.4 Transitions between CPW and other Mediums 495 -- 17.5 Slotline Transitions 498 -- 17.6 Other Microstrip Transitions 510 -- 17.7 Summary 511 -- References 511 -- 18 Measurements of Planar Transmission Line Structures 514 -- 18.1 Introduction 514 -- 18.2 Instrumentation Systems for Microstrip Measurements 514 -- 18.3 Measurement of Scattering Parameters 515 -- 18.4 Measurement of Substrate Properties 519 -- 18.5 Microstrip Resonator Methods 523 -- 18.6 Q Factor Measurements 533 -- 18.7 Measurements of Parallel-coupled Microstrips 535 -- 18.8 Time-domain Reflectometry Techniques 537 -- 18.9 Summary 539 -- References 539 -- 19 Filters Using Planar Transmission Lines 541 -- 19.1 Introduction 541 -- 19.2 Filter Prototypes 541 -- 19.2.7 Moderate Bandwidth Transmission Line Stub Model of an Inverter 550 -- 19.3 Microstrip Filters 554 -- 19.4 Microstrip Bandpass Filters 559 -- 19.5 Parallel-coupled Line Bandpass Filters 561 -- 19.6 Filter Design Accounting for Losses 572 -- 19.7 Dielectric Resonators and Filters Using Them 572 -- 19.8 Spurline Bandstop Filters 573 -- 19.9 Summary 575 -- References 575 -- 20 Magnetic Materials and Planar Transmission Lines 576.

20.1 Introduction 576 -- 20.2 Microwave Magnetic Materials 577 -- 20.3 Effective Permeability of Magnetic Materials 587 -- 20.4 Microstrip on a Ferrite Substrate 589 -- 20.5 Isolators and Circulators 592 -- 20.6 Transmission Lines Using Metaconductors 595 -- 20.7 Frequency Selective Limiter 606 -- 20.8 Summary 607 -- References 607 -- 21 Interconnects for Digital Systems 610 -- 21.1 Introduction 610 -- 21.2 Overview of On-chip Interconnects 610 -- 21.3 RC Modeling of On-chip Interconnects 613 -- 21.4 Modeling Inductance 619 -- 21.5 Clock Distribution 622 -- 21.6 Resonant Clock Distribution 625 -- 21.7 Summary 626 -- References 627 -- A Physical

and Mathematical Properties 629 -- A.1 SI Units 629 -- A.2 SI Prefixes 629 -- A.3 Physical and Mathematical Constants 631 -- A.4 Basis of Electromagnetic SI Units 631 -- A.5 Relationship of SI Units to CGS Units 632 -- B Material Properties 635 -- References 642 -- C RF and Microwave Substrates 643 -- C.1 Hard substrates 643 -- C.2 Soft Substrates 644 -- Index 647.

Bielefeld, : transcript Verlag, 2014

2014, c2010

9783839413746

3839413745

1 online resource (233 p.)

Urbane Welten - Texte zur kulturwissenschaftlichen Stadtforschung ; 3

338.47306091732

Urban

City

Policy

Economy

Culture

Creativity

Urbanity

Urban Studies

Cultural Industry

Cultural Geography

Cultural Studies

Sociology

Inglese

Description based upon print version of record.

Includes bibliographical references.

1 CONTENTS    5 ACKNOWLEDGMENTS    9 1. INTRODUCTION    11 2.

CULTURAL POLITICAL ECONOMY AND EMPIRICAL RESEARCH    27 3. ACCUMULATION, REGULATION, NETWORKS    65 4. LOCATION    99 5. COMMUNICATION    123 6. LABOR    169 7. CONCLUDING COMMENTS    191 REFERENCES    201

This book offers a fundamental contribution to the literature on the creative industries and the knowledge-based economy by focusing on three aspects: urban spaces as key sites of capitalist restructuring, creative industries' policies as state technologies aimed at economic exploitation, and the role of networks of aesthetic production in inflecting these tendencies. It simultaneously goes beyond these debates by integrating a concern with the cultural and aesthetic dimensions of the creative industries. As such, the book is relevant to researchers interested in the transdisciplinary project of a cultural political economy of creativity and urban change.