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Beyond 100: The Next Century in Geodesy Proceedings of the IAG General Assembly, Montreal, Canada, July 8-18, 2019 /
Published 2022Table of Contents: “…Part I: Reference Systems and Frames -- Towards an International Height Reference Frame Using Clock Networks -- Towards the realization of the International Height Reference Frame (IHRF) in Argentina -- Comparing Vienna CRF solutions to Gaia-CRF2 -- Co-Location of Space Geodetic Techniques: Studies on Intra-Technique Short Baselines -- Status of IGS Reprocessing Activities at GFZ -- A Wavelet-based Outlier Detection and Noise Component Analysis for GNSS Position Time Series -- Part II: Gravity field modelling -- International Combination Service for Time-variable Gravity Fields (COST-G) - Start of operational phase and future perspectives -- LUH-GRACE2018: a new time series of monthly gravity field solutions from GRACE -- A Precise Geoid Model for Africa: AFRgeo2019 -- Part III: Earth rotation and geodynamics -- A first assessment of the corrections for the consistency of the IAU2000 and IAU2006 precession-nutation models -- Report of the IAU/IAG Joint Working Group on Theory of Earth rotation andvalidation -- Achievements of the first 4 years of the International Geodynamics and Earth Tide Service (IGETS) 2015 - 2019 -- Inter-comparison of ground gravity and vertical height measurements at collocated IGETS stations -- Part IV: Multi-Signal Positioning, Remote Sensing and Applications -- A Benchmarking Measurement Campaign to Support Ubiquitous Localization in GNSS Denied and Indoor Environments -- A method to correct the raw Doppler observations for GNSS velocity determination -- Assessment of a GNSS/INS/Wi-Fi Tight-Integration Method Using Support Vector Machine and Extended Kalman Filter -- Enhancing navigation in difficult environments with low-cost, dual-frequency GNSS PPP and MEMS IMU -- Part V: Monitoring and Understanding the Dynamic Earth with Geodetic Observations -- Water Depletion and Land Subsidence in Iran using Gravity, GNSS, InSAR and Precise Levelling Data -- Past and future sea level changes and land uplift in the Baltic Sea seen by geodetic observations -- Estimation ofLesser Antilles vertical velocity fields using a GNSS-PPP software comparison -- Time variations of the vertical component in Japanese GEONET GNSS sites -- An approximate method to simulate post-seismic deformations in a realistic Earth model -- Geodetic monitoring of the variable surface 1 deformation in Latin America -- Progress in GTEWS ground displacement measurements and tsunami warning -- Part VI: Geodesy for Atmospheric and Hydrospheric Climate Research (IAG, IAMAS, IACS, IAPSO) -- Characterization of the Upper Atmosphere from Neutral and Electron Density Observations -- Tropospheric products from high-level GNSS processing in Latin America -- Can vertical GPS displacements serve as proxies for climate variability in North America? …”
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2238
Semiconductor Devices Theory and Application
Published 2018Table of Contents: “…Chapter 1: Semiconductor Fundamentals -- 1.0 Chapter Objectives -- 1.1 Introduction -- 1.2 Atomic Structure -- 1.3 Crystals -- 1.4 Doped Materials -- Summary -- Chapter 2: PN Junctions and Diodes -- 2.0 Chapter Objectives -- 2.1 Introduction -- 2.2 The PN Junction -- 2.3 Diode Data Sheet Interpretation -- 2.4 Diode Circuit Models -- 2.5 Other Types of Diodes -- Summary -- Chapter 3: Diode Applications -- 3.0 Chapter Objectives -- 3.1 Introduction -- 3.2 Rectification -- 3.3 Clippers -- 3.4 Clampers -- Summary -- Chapter 4: Bipolar Junction Transistors (BJTs) -- 4.0 Chapter Objectives -- 4.1 Introduction -- 4.2 The Bipolar Junction Transistor -- 4.3 BJT Collector Curves -- 4.4 BJT Data Sheet Interpretation -- 4.5 Ebers-Moll Model -- 4.6 DC Load Lines -- 4.7 BJT Switching and Driver Applications -- Summary -- Chapter 5: BJT Biasing -- 5.0 Chapter Objectives -- 5.1 Introduction -- 5.2 The Need For Biasing -- 5.3 Two-Supply Emitter Bias -- 5.4 Voltage Divider Bias -- 5.5 Feedback Biasing -- Summary -- Chapter 6: Amplifier Concepts -- 6.0 Chapter Objectives -- 6.1 Introduction -- 6.2 Amplifier Model -- 6.3 Compliance and Distortion -- 6.4 Frequency Response and Noise -- 6.5 Miller's Theorem -- Summary -- Chapter 7: BJT Small Signal Amplifiers -- 7.0 Chapter Objectives -- 7.1 Introduction -- 7.2 Simplified AC Model of the BJT -- 7.3 Common Emitter Amplifier -- 7.4 Common Collector Amplifier -- 7.5 Common Base Amplifier -- 7.6 Multi-Stage Amplifiers -- Summary -- Chapter 8: BJT Class A Power Amplifiers -- 8.0 Chapter Objectives -- 8.1 Introduction -- 8.2 Amplifier Classes -- 8.3 Class A Operation and Load Lines -- 8.4 Loudspeakers -- 8.5 Power Transistor Data Sheet Interpretation -- 8.6 Heat Sinks -- Summary -- Chapter 9: BJT Class B Power Amplifiers -- 9.0 Chapter Objectives -- 9.1 Introduction -- 9.2 The Class B Configuration -- 9.3 Extensions and Refinements -- Summary -- Chapter 10: Junction Field Effect Transistors (JFETs) -- 10.0 Chapter Objectives -- 10.1 Introduction -- 10.2 JFET Internals -- 10.3 JFET Data Sheet Interpretation -- 10.4 JFET Biasing -- Summary -- Chapter 11: JFET Small Signal Amplifiers -- 11.0 Chapter Objectives -- 11.1 Introduction -- 11.2 Simplified AC Model of the JFET -- 11.3 Common Source Amplifier -- 11.4 Common Drain Amplifier -- 11.5 Multi-stage and Combination Circuits -- 11.6 Ohmic Region Operation -- Summary -- Chapter 12: Metal Oxide Semiconductor FETs (MOSFETs) -- 12.0 Chapter Objectives -- 12.1 Introduction -- 12.2 The DE-MOSFET -- 12.3 DE-MOSFET Biasing -- 12.4 The E-MOSFET -- 12.5 E-MOSFET Data Sheet Interpretation -- 12.6 E-MOSFET Biasing -- Summary -- Chapter 13: MOSFET Small Signal Amplifiers -- 13.0 Chapter Objectives -- 13.1 Introduction -- 13.2 MOSFET Common Source Amplifiers -- 13.3 MOSFET Common Drain Followers -- Summary -- Chapter 14: Class D Power Amplifiers -- 14.0 Chapter Objectives -- 14.1 Introduction -- 14.2 Class D Basics -- 14.3 Pulse Width Modulation -- 14.4 Output Configurations -- Summary -- Chapter 15: Insulated Gate Bipolar Transistors (IGBTs) -- 15.0 Chapter Objectives -- 15.1 Introduction -- 15.2 IGBT Internals -- 15.3 IGBT Data Sheet Interpretation -- 15.4 IGBT Applications -- Summary…”
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2239
Operational Amplifiers & Linear Integrated Circuits Theory and Application
Published 2018Table of Contents: “…-- 2.3 Simple Op Amp Comparator -- 2.4 Op Amp Manufacture -- Summary -- Chapter 3: Negative Feedback -- 3.1 Introduction -- 3.2 What Negative Feedback Is and Why We Use It -- 3.3 Basic Concepts -- 3.4 The Four Variants of Negative Feedback -- 3.5 Limitations On The Use of Negative Feedback -- Summary -- Chapter 4: Basic Op Amp Circuits -- 4.1 Introduction -- 4.2 Inverting and Non-inverting Amplifiers -- 4.3 Single Supply Biasing -- 4.4 Current Boosting -- Summary -- Chapter 5: Practical Limitations of Op Amp Circuits -- 5.1 Introduction -- 5.2 Frequency Response -- 5.3 Gain-Bandwidth Product -- 5.4 Slew Rate and Power Bandwidth -- 5.5 Offsets -- 5.6 Drift -- 5.7 CMRR and PSRR -- 5.8 Noise -- Summary -- Chapter 6: Specialized Op Amps -- 6.1 Introduction -- 6.2 Instrumentation Amplifiers -- 6.3 Programmable Op Amps -- 6.4 Op Amps for High Current, Power, and Voltage Applications -- 6.5 High Speed Amplifiers -- 6.6 Voltage Followers and Buffers -- 6.7 Operational Transconductance Amplifier -- 6.8 Norton Amplifier -- 6.9 Current Feedback Amplifiers -- 6.10 Other Specialized Devices -- Summary -- Chapter 7: Non-Linear Circuits -- 7.1 Introduction -- 7.2 Precision Rectifiers -- 7.3 Wave Shaping -- 7.4 Function Generation -- 7.5 Comparators -- 7.6 Log and Anti-Log Amplifiers -- 7.7 Extended Topic: A Precision Log Amp -- Summary -- Chapter 8: Voltage Regulation -- 8.1 Introduction -- 8.2 The Need For Regulation -- 8.3 Linear Regulators -- 8.4 Switching Regulators -- 8.5 Heat Sink Usage -- 8.6 Extended Topic: Primary Switcher -- Summary -- Chapter 9: Oscillators and Frequency Generators -- 9.1 Introduction -- 9.2 Op Amp Oscillators -- 9.3 Single Chip Oscillators and Frequency Generators -- Summary -- Chapter 10: Integrators and Differentiators -- 10.1 Introduction -- 10.2 Integrators -- 10.3 Differentiators -- 10.4 Analog Computer -- 10.5 Alternatives to Integrators and Differentiators -- 10.6 Extended Topic: Other Integrator and Differentiator Circuits -- Summary -- Chapter 11: Active Filters -- 11.1 Introduction -- 11.2 Filter Types -- 11.3 The Use and Advantages of Active Filters -- 11.4 Filter Order and Poles -- 11.5 Filter Class or Alignment -- 11.6 Realizing Practical Filters -- 11.7 Band-Pass Filter Realizations -- 11.8 Notch Filter (Band-Reject) Realizations -- 11.9 Audio Equalizers -- 11.10 Switched-Capacitor Filters -- 11.11 Extended Topic: Voltage-Controlled Filters -- Summary -- Chapter 12: Analog-to-Digital-to-Analog Conversion -- 12.1 Introduction -- 12.2 The Sampling Theorem -- 12.3 Resolution and Sampling Rate -- 12.4 Digital-to-Analog Conversion Techniques -- 12.5 Analog-to-Digital Conversion -- 12.6 Extended Topic: Digital Signal Processing -- Summary --…”
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