Analysis and Application of Analog Electronic Circuits to Biomedical Instrumentation

All chapters include an introduction and chapter summary.

Sources and Properties of Biomedical Signals
Sources of Endogenous Bioelectric Signals
Nerve Action Potentials
Muscle Action Potentials
The Electrocardiogram
Other Biopotentials
Electrical Properties of Bioelectrodes
Exogenous Bioelectric Signals

Properties and Models of Semiconductor Devices Used in Analog Electronic Systems
pn Junction Diodes
Midfrequency Models for BJT Behavior
Midfrequency Models for Field-Effect Transistors
High-Frequency Models for Transistors and Simple Transistor Amplifiers
Photons, Photodiodes, Photoconductors, LEDs, and Laser Diodes

The Differential Amplifier
DA Circuit Architecture
Common-Mode Rejection Ratio
CM and DM Gain of Simple DA Stages at High Frequencies
Input Resistance of Simple Transistor DAs
How Signal Source Impedance Affects the Low-Frequency CMRR
How Op Amps Can be Used to Make DAs for Medical Applications

General Properties of Electronic, Single-Loop Feedback Systems
Classification of Electronic Feedback Systems
Some Effects of Negative Voltage Feedback
Effects of Negative Current Feedback
Positive Voltage Feedback

Feedback, Frequency Response, and Amplifier Stability
Review of Amplifier Frequency Response
What Is Meant by Feedback System Stability
The Use of Root Locus in Feedback Amplifier Design
Use of Root-Locus in the Design of "Linear" Oscillators

Operational Amplifiers and Comparators
The Ideal Op Amp
Practical Op Amps
Gain-Bandwidth Relations for Voltage-Feedback OAs
Gain-Bandwidth Relations in Current Feedback Amplifiers
Analog Voltage Comparators
Some Applications of Op Amps in Biomedicine

Introduction to Analog Active Filters
Active Filter Applications
Types of Analog Active Filters
Electronically Tunable AFs

Instrumentation and Medical Isolation Amplifiers
Instrumentation Amps
Medical Isolation Amps
Safety Standards in Medical Electronic Amplifiers
Medical-Grade Power Supplies

Noise and the Design of Low-Noise Signal Conditioning Systems for Biomedical Applications
Descriptors of Random Noise in Biomedical Measurement Systems
Propagation of Noise Through LTI Filters
Noise Factor and Figure of Amplifiers
Cascaded Noisy Amplifiers
Noise in Differential Amplifiers
Effect of Feedback on Noise
Examples of Noise-Limited Resolution of Certain Signal Conditioning Systems
Some Low-Noise Amplifiers
The Art of Low-Noise Signal Conditioning System Design

Digital Interfaces
Aliasing and the Sampling Theorem
Digital-to-Analog Converters
Sample-and-Hold Circuits
Analog-to-Digital Converters
Quantization Noise

Modulation and Demodulation of Biomedical Signals
Modulation of a Sinusoidal Carrier Viewed in the Frequency Domain
Implementation of AM
Generation of Phase and Frequency Modulation
Demodulation of Modulated Sinusoidal Carriers
Modulation and Demodulation of Digital Carriers

Power Amplifiers and Their Applications in Biomedicine
Power Output Devices
Classes of Power Amplifiers: PA Efficiency
Class D Power Amplifiers
Nonlinearity and Distortion in PAs
IC Voltage Regulators in Medical Electronic Systems
Heatsinking

Wireless Patient Monitoring
Sensors and Sensor Signals Communicated in WPM
Modulation in WPM
RF Communications Protocols Used in WPM
UHF Transmitters and Antennas
WPM Systems
How WPM Reduces the Probability of Patient Microshock
Privacy in WPM

RFID Tags, GPS Tags, and Ultrasonic Tags Used in Ecological Research
Applications of RFID Tags
Design of RFID Tags
Tag Readers
GPS Tags
Ultrasonic Tags in Fisheries Biology

Examples of Special Analog Circuits and Systems Used in Biomedical Instrumentation
The Phase-Sensitive Rectifier
Phase Detectors
Voltage and Current-Controlled Oscillators
Phase-Lock Loops
True RMS Converters
IC Temperature Sensors
Three Examples of Medical Instrumentation Systems

Appendix
Glossary
Bibliography and Recommended Reading

Biography

Robert B. Northrop is Professor Emeritus and the former Program Director of the Biomedical Engineering Graduate Program at the University of Connecticut.