Sources and Properties of Biomedical Signals Properties and Models of Semiconductor Devices Used in Analog Electronic Systems The Differential Amplifier General Properties of Electronic, Single-Loop Feedback Systems Feedback, Frequency Response, and Amplifier Stability Operational Amplifiers and Comparators Introduction to Analog Active Filters Instrumentation and Medical Isolation Amplifiers Noise and the Design of Low-Noise Signal Conditioning Systems for Biomedical Applications Digital Interfaces Modulation and Demodulation of Biomedical Signals Power Amplifiers and Their Applications in Biomedicine Wireless Patient Monitoring RFID Tags, GPS Tags, and Ultrasonic Tags Used in Ecological Research Examples of Special Analog Circuits and Systems Used in Biomedical Instrumentation

This text is intended for use in a classroom course on Analysis and Application of Analog Electronic Circuits to Biomedical Instrumentation taken by junior or senior undergraduate students specializing in Biomedical Engineering. It focuses on the electronic components and subsystems that makeup the diverse instruments that are used in biomedical instrumentation. It will also serve as a reference book for biophysics and medical students interested in the topics. Readers are assumed to have had introductory, core courses up to the junior level in engineering mathematics, including complex algebra, calculus, and introductory differential equations. They also should have taken a college physics course containing electricity and magnetism. As the result of taking these courses, readers should be familiar with systems block diagrams, the concepts of frequency response and transfer functions, and should be able to solve simple, linear, ordinary differential equations, and do basic manipulations in linear algebra. It is also important to have an understanding of the working principles of the various basic solid-state devices (diodes, bipolar junction transistors, and field effect transistors) used in electronic circuits with biomedical applications. Rationale The interdisciplinary field of Biomedical Engineering is demanding in that it requires its followers to know and master not only certain engineering skills (electronics, materials, mechanical, and photonic) but also a diversity of material in the biological sciences (anatomy, biochemistry, molecular biology, genomics, physiology, etc.