Addresses measurements in new fields such as cellular and molecular biology. Equips readers with the necessary background in electric circuits. Statistical coverage shows how to determine trial sizes.
Bioinstrumentation deals with the instrumentation techniquesand principles used for measuring physical, physiological,biochemical and biological factors in man or other livingorganisms. This book provides a comprehensive knowledgeabout the basic principles and applications of the tools andtechniques generally used in biology and also those used in thegrowing field of molecular biology. This book will prove to be adependable reference book for students and teachers ofbiological sciences.
This short book provides basic information about bioinstrumentation and electric circuit theory. Many biomedical instruments use a transducer or sensor to convert a signal created by the body into an electric signal. Our goal here is to develop expertise in electric circuit theory applied to bioinstrumentation. We begin with a description of variables used in circuit theory, charge, current, voltage, power and energy. Next, Kirchhoff's current and voltage laws are introduced, followed by resistance, simplifications of resistive circuits and voltage and current calculations. Circuit analysis techniques are then presented, followed by inductance and capacitance, and solutions of circuits using the differential equation method. Finally, the operational amplifier and time varying signals are introduced. This lecture is written for a student or researcher or engineer who has completed the first two years of an engineering program (i.e., 3 semesters of calculus and differential equations). A considerable effort has been made to develop the theory in a logical manner--developing special mathematical skills as needed. At the end of the short book is a wide selection of problems, ranging from simple to complex.
This reference text consists of contributed chapters by specialists directly carrying out research and development in this emerging field which joins advanced microelectronics with modern biotechnology. Chapters present novel biotechnology-based microelectronic instruments, such as those used for de
This short book provides basic information about bioinstrumentation and electric circuit theory. Many biomedical instruments use a transducer or sensor to convert a signal created by the body into an electric signal. Our goal here is to develop expertise in electric circuit theory applied to bioinstrumentation. We begin with a description of variables used in circuit theory, charge, current, voltage, power and energy. Next, Kirchhoff's current and voltage laws are introduced, followed by resistance, simplifications of resistive circuits and voltage and current calculations. Circuit analysis techniques are then presented, followed by inductance and capacitance, and solutions of circuits using the differential equation method. Finally, the operational amplifier and time varying signals are introduced. This lecture is written for a student or researcher or engineer who has completed the first two years of an engineering program (i.e., 3 semesters of calculus and differential equations). A considerable effort has been made to develop the theory in a logical manner—developing special mathematical skills as needed. At the end of the short book is a wide selection of problems, ranging from simple to complex.
This reference on bioinstrumentation describes the world of medical electronics. Bioinstruments measure, record and transmit data on bodily functions. The entire text is covered in 19 chapters and each chapter covers all the topics in a cogent and lucid style to help the reader grasp the information quickly and easily.
This is the eBook version of the print title. The eBook edition does not provide access to the content of the CD ROMs that accompanies the print book. Bringing the power of virtual instrumentation to the biomedical community. Applications across diverse medical specialties Detailed design guides for LabVIEW and BioBench applications Hands-on problem-solving throughout the book Laboratory, clinical, and healthcare applications Numerous VI's with source code, plus several demos, are available on the book's web site Virtual instrumentation allows medical researchers and practitioners to combine the traditional diagnostic tools with advanced technologies such as databases, Active X, and the Internet. In both laboratory and clinical environments, users can interact with a wealth of disparate systems, facilitating better, faster, and more informed decision making. Virtual Bio-Instrumentation: Biomedical, Clinical, and Healthcare Applications in LabVIEW is the first book of its kind to apply VI technology to the biomedical field. Hands-on problems throughout the book demonstrate immediate practical uses Examples cover a variety of medical specialties Detailed design instructions give the inside view of LabVIEW and BioBench applications Both students and practicing professionals will appreciate the practical applications offered for modeling fundamental physiology, advanced systems analysis, medical device development and testing, and even hospital management and clinical engineering scenarios.
Review of electronic devices. Operational amplifiers and instrumentation amplifiers. Linear systems theory. Origin of biopotentials. human biopotentials. Signals and noise in biological systems. Biopotential electrodes. Ion-sensitive, potentiometric, and amperometric electrodes. Mechanical transducers. Temperature transducers. Light and spectrophotometry. Measurement of liquid and gas flows. Analog linearization. Review of digital electronic devices. Talking to computers. Interfacing computers to the outside world. Digital signal processing. Safety in bioinstrumentation. Data sheets.