000			04272cam a2200505Ia 4500
001			u369596
003			SIRSI
005			20160812080001.0
006			m o d
007			cr mnu||||||||
008			061102s2006 caua o 000 0 eng d
040			_aWAU _beng _cWAU _dBAKER _dHKP _dWAU _dUMC _dWAU _dCUS _dPUL _dCIT _dCEF _dOCLCQ _dE7B _dQE2 _dNT _dEBLCP _dOCLCQ
019			_a456124403 _a785776080
020			_a1598291335 (ebook)
020			_a9781598291339 (ebook)
020			_a1598291327 (pbk.)
020			_a9781598291322 (pbk.)
050		4	_aQH324.42 _b.E64 2006
082	0	4	_a610.28/4 _222
096			_aQT 36 _bE56 2006
049			_aMAIN
100	1		_aEnderle, John D. _q(John Denis)
245	1	0	_aBioinstrumentation _h[recurso electrónico] / _cJohn D. Enderle.
250			_a1st ed.
260			_a[San Rafael, Calif.] : _bMorgan & Claypool Publishers, _cc2006.
300			_a1 online resource (vii, 212 p.)
490	1		_aSynthesis lectures on biomedical engineering, _x1930-0336 ; _v#6
500			_aTitle from PDF t.p. (viewed Nov. 2, 2006).
505	0		_aIntroduction -- Basic bioinstrumentation system -- Charge, current, voltage, power and energy -- Charge -- Current -- Voltage -- Power and energy -- Sources -- Resistance -- Resistors -- Power -- Equivalent resistance -- Series and parallel combinations of resistance -- Voltage and current divider rules -- Linear network analysis -- Node-voltage method -- Mesh-current method -- Linearity, superposition and source transformations -- Thevenin's and Norton's theorems -- Thevenin's theorem -- Norton's theorem -- Dependent sources and Thevenin and Norton equivalent circuits -- Inductors -- Power and energy -- Capacitors -- Power and energy -- Inductance and capacitance combinations -- General approach to solving circuits involving resistors, capacitors and inductors -- Discontinuities and initial conditions in a circuit -- Circuits with switches -- Operational amplifiers --Voltage characteristics of the Op amp -- Time-varying signals -- Phasors -- Passive circuit elements in the phasor domain -- Kirchhoff's laws and other techniques in the phasor domain -- Active analog filters -- Bioinstrumentation design -- Noise --Computers -- Exercises.
520			_aThis 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.
504			_aIncludes bibliographical references.
650	1	2	_aBiomedical Engineering _xinstrumentation.
650	2	2	_aElectronics, Medical _xinstrumentation.
650		0	_aMedical instruments and apparatus.
650		0	_aBiomedical engineering _xInstruments.
650		0	_aElectric circuits.
650		7	_aMEDICAL / Instruments & Supplies _2bisacsh
655		4	_aElectronic books.
830		0	_aSynthesis lectures on biomedical engineering (Online) ; _v#6.
856	4	0	_zLibro electrónico _uhttp://148.231.10.114:2048/login?url=http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&an=440155
596			_a19
942			_cLIBRO_ELEC
999			_c197798 _d197798