| Description |
1 online resource |
|
data file rda |
| Series |
Focus series |
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Focus series (London, England)
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| Bibliography |
Includes bibliographical references and index. |
| Summary |
Many instrumentation engineers and scientists often deal with analog electronic issues when approaching delicate measurements. Even if off-the-shelf measuring solutions exist, comprehension of the analog behavior of the measuring system is often a necessity. This book provides a concise introduction to the main elements of a low frequency analog acquisition chain. It aims to be sufficiently general to provide an introduction, yet specific enough to guide the reader through some classical problems that may be encountered in the subject. Topics include sensors, conditioning circuits, differential and instrumentation amplifiers, active filters (mainly for anti-aliasing purposes) and analog to digital converters. A chapter is devoted to an introduction to noise and electronic compatibility. This work is intended for people with a general background in electronics and signal processing, who are looking for an introduction to classical electronic solutions employed in measuring instruments involving low frequency analog signal processing. |
| Contents |
Ch. 1 Fundamentals of Sensing and Signal Conditioning -- 1.1. Introduction -- 1.2. Voltage generating sensors -- 1.2.1. General description -- 1.2.2. Examples -- 1.3. Current generating sensors -- 1.3.1. General description -- 1.3.2. Examples -- 1.3.3. Conditioning circuits -- 1.4. Charge generating sensors -- 1.4.1. General description -- 1.4.2. Examples -- 1.4.3. Conditioning -- 1.5. Resistive sensors -- 1.5.1. Examples -- 1.5.2. Caveats -- 1.5.3. Signal conditioning: measuring the total resistance -- 1.5.4. Measuring a resistance variation: the Wheatstone bridge -- 1.6. Reactive sensors -- 1.7. Conclusion -- ch. 2 Amplification and Amplifiers -- 2.1. Introduction -- 2.2. Introduction to operational amplifiers -- 2.2.1. The operational amplifier as a differential amplifier -- 2.2.2. Modeling ideal operational amplifiers -- 2.3. Limitations of real operational amplifiers -- 2.3.1. Saturation and rail-to-rail operational amplifiers -- 2.3.2. Input offset -- 2.3.3.Common mode rejection ratio -- 2.3.4. Bias currents -- 2.3.5. Stability and frequency response -- 2.3.6. Examples -- 2.4. Instrumentation amplifiers -- 2.4.1. Introduction -- 2.4.2. Differential amplifier with one operational amplifier -- 2.4.3. Differential amplifier with two operational amplifiers -- 2.4.4. Differential amplifier with three operational amplifiers -- 2.5. Isolation amplifiers -- 2.6. Conclusion -- ch. 3 Elements of Active Filter Synthesis -- 3.1. Introduction -- 3.2. Low-pass filter approximation -- 3.2.1. Aliasing in sampled systems and anti-aliasing filters -- 3.2.2. Definitions -- 3.2.3. All-pole filters: normalization and factorization -- 3.2.4. Butterworth approximation -- 3.2.5. Chebyshev approximation -- 3.2.6. Bessel -- Thompson approximation -- 3.2.7. Examples -- 3.3. Active filter synthesis by means of standard cells -- 3.3.1. Low-pass Sallen-Key cell: a pair of complex conjugate poles -- 3.3.2. Low-pass active RC cell: a real negative pole -- 3.3.3. Cell order -- 3.4. Frequency transform techniques -- 3.4.1. High-pass filters -- 3.4.2. Band-pass filters -- 3.4.3. Band-reject (notch) filters -- 3.4.4. High-pass and band-pass cells -- 3.5. Conclusion -- ch. 4 Analog to Digital Converters -- 4.1. Digital to analog converters and analog to digital converters: an introduction -- 4.2. Notations and digital circuits -- 4.3. Sample and hold circuits -- 4.4. Converter structures -- 4.4.1. General features -- 4.4.2. Flash ADCs -- 4.4.3.A Simple DAC: R2R Ladder -- 4.4.4. Half-flash and pipeline ADCs -- 4.4.5. Successive approximation converters -- 4.4.6. Single- and double-ramp converters -- 4.4.7. Sigma-delta converters -- 4.5. No silver bullet: choosing the best trade-off -- 4.5.1. Conversion errors and artifacts -- 4.5.2. Performances of typical converters -- 4.6. Conclusion -- ch. 5 Introduction to Noise Analysis in Low Frequency Circuits -- 5.1. What is noise -- 5.2. Stochastic modeling of a noise -- 5.2.1. Some definitions -- 5.2.2. Measurement units for pB(b) and?B(f) -- 5.2.3. Negative and positive frequencies -- 5.3. Different kinds of stochastic noises -- 5.3.1. Thermal noise (Johnson -- Nyquist) -- 5.3.2. Flicker or 1/f noise -- 5.3.3. Avalanche or breakdown noise -- 5.3.4. Burst or "popcorn" or random telegraph signal noise -- 5.3.5. Shot noise or Poisson noise -- 5.4. Limits of modeling -- 5.5. Contributions from stochastically independent noise sources -- 5.6. Noise equivalent bandwidth and noise factor -- 5.7. Amplifiers and noise -- 5.7.1. Noise models of operational amplifiers -- 5.7.2. Example: noise factor of a non-inverting amplifier -- 5.7.3. Noise models of instrumentation amplifiers -- 5.8. Noise from "outer space": electromagnetic compatibility -- 5.9. Conclusion. |
| Subject |
Analog electronic systems.
|
|
Systèmes analogiques. |
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Analog electronic systems |
| Other Form: |
Print version: Bucci, Davide, 1979- Analog electronics for measuring systems. London, UK : ISTE ; Hoboken, NJ : Wiley, 2017 1786301482 9781786301482 (OCoLC)978644198 |
| ISBN |
9781119405153 (electronic bk.) |
|
1119405157 (electronic bk.) |
|
9781119405177 (electronic bk.) |
|
1119405173 (electronic bk.) |
|
(print) |
|
9781119405160 |
|
1119405165 |
|
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