Op amps for everyone

Op amps for everyone

Op Amps for Everyone is an indispensable guide and reference for designing circuits that are reliable, have low power consumption, and are as small and low-cost as possible. Operational amplifiers are essential in modern electronics design, and are used in medical devices, communications technology,...

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Detalles Bibliográficos
Autor principal: Carter, Bruce (-)
Formato: Libro electrónico
Idioma:Inglés
Publicado: Oxford : Newnes 2013.
Oxford : 2013.
Edición:4th ed
Colección:Gale eBooks
Materias:
Operational amplifiers.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009628569506719
Tabla de Contenidos:
  • Front Cover; Op Amps for Everyone; Copyright Page; Contents; List of Figures; List of Tables; List of Abbreviations; 1 The Op Amp's Place in the World; 1.1 An Unbounded Gain Problem; 1.2 The Solution; 1.3 The Birth of the Op Amp as a Component; 1.3.1 The Vacuum Tube Era; 1.3.2 The Transistor Era; 1.3.3 The Integrated Circuit Era; Reference; 2 Review of Op Amp Basics; 2.1 Introduction; 2.2 Basic Concepts; 2.2.1 Ohm's Law; 2.2.2 The Voltage Divider Rule; 2.2.3 Superposition; 2.3 Basic Op Amp Circuits; 2.3.1 The Non-Inverting Op Amp; 2.3.2 The Inverting Op Amp; 2.3.3 The Adder
  • 4.2 Uncompensated/Undercompensated Voltage Feedback Op Amps4.3 Current Feedback Op Amps; 4.4 Fully Differential Op Amps; 4.4.1 What Does "Fully Differential" Mean?; 4.4.2 How is the Second Output Used?; 4.4.3 Differential Gain Stages; 4.4.4 Single-Ended to Differential Conversion; 4.4.5 A New Function; 4.5 Instrumentation Amplifier; 4.6 Difference Amplifier; 4.7 Buffer Amplifiers; 4.8 Other Types of Op Amps; 5 Interfacing a Transducer to an Analog-to-Digital Converter; 5.1 Introduction; 5.2 System Information; 5.3 Power Supply Information; 5.4 Input Signal Characteristics
  • 5.5 Analog-to-Digital Converter Characteristics5.6 Interface Characteristics; 5.7 Architectural Decisions; 5.8 Conclusions; 6 Active Filter Design Techniques; 6.1 Introduction; 6.2 The Transfer Equation Method; 6.3 Fast, Practical Filter Design; 6.3.1 Picking the Response; 6.3.2 Low-Pass Filter; Design Procedure; Digging Deeper; 6.3.3 High-Pass Filter; Design Procedure; Digging Deeper; 6.3.4 Narrow (Single-Frequency) Bandpass Filter; Design Procedure; Digging Deeper; 6.3.5 Wide Bandpass Filter; Design Procedure; Digging Deeper; Digging Deeper: Narrow vs. Wide Bandpass Filter
  • 6.3.6 Notch (Single-Frequency Rejection) FilterDesign Procedure; Digging Deeper; 6.4 High-Speed Filter Design; 6.4.1 High-Speed Low-Pass Filters; 6.4.2 High-Speed High-Pass Filters; 6.4.3 High-Speed Bandpass Filters; 6.4.4 High-Speed Notch Filters; 6.5 Getting the Most Out of a Single Op Amp; 6.5.1 Three-Pole Low-Pass Filters; 6.5.2 Three-Pole High-Pass Filters; 6.5.3 Stagger-Tuned and Multiple-Peak Bandpass Filters; 6.5.4 Single-Amplifier Notch and Multiple-Notch Filters; 6.5.5 Combination Bandpass and Notch Filters; 6.6 Biquad Filters; 6.7 Design Aids
  • 6.7.1 Low-Pass, High-Pass, and Bandpass Filter Design Aids

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