Principles of Biomedical Instrumentation and Measurement
A contemporary new text for preparing students to work with the complex patient-care equipment found in today's modern hospitals and clinics. It begins by presenting fundamental prerequisite concepts of electronic circuit theory, medical equipment history and physiological transducers, as well as a systematic approach to troubleshooting. The text then goes on to offer individual chapters on common and speciality medical equipment, both diagnostic and therapeutic. Self-contained, these chapters can be used in any order, to fit the instructor's class goals and syllabus.
24 pages matching radiation in this book
Results 1-3 of 24
A Perspective on Medical Instrumentation
The Origin of Biopotentials
22 other sections not shown
action potential analysis anode applied battery beam biopotential block diagram body calculation capacitance capacitor catheter cathode cause chassis chip common-mode components Compute connected Courtesy defibrillator depolarization device diff amp differential amplifier diode electrical electrocardiograph energy Equation equivalent circuit example fibrillation filter flow fluid frequency function gain given in Figure heart ideal illustrated in Figure ions KEY STEP KEY KOUT laser lead leakage current lung measured Medical Instrumentation membrane meter microprocessor microshock monitor muscle node Ohm's law operation operational amplifier output voltage pacemaker patient phasor plot positive potential power supply pressure pulse radiation resistance resistor shown in Figure signal skin SOLUTION STEP KEY STEP strain gauge surface electrodes switch temperature thermistor tion tissue transducer transistor troubleshooting ultrasonic unit valve ventricle versus voltage division VOVT wave waveform Wheatstone bridge wire x-ray tube zero