000 08961nam a2200541 i 4500
001 6812788
003 IEEE
005 20200413152853.0
006 m eo d
007 cr cn |||m|||a
008 090309s2009 caua foab 000 0 eng d
020 _a9781598299519 (electronic bk.)
020 _a9781598299502 (pbk.)
024 7 _a10.220/S00157ED1V01Y200812BME027
_2doi
035 _a(CaBNVSL)gtp00533528
035 _a(OCoLC)317665512
040 _aCaBNVSL
_cCaBNVSL
_dCaBNVSL
050 4 _aQH508
_b.L473 2009
082 0 4 _a574.188
_222
100 1 _aLessard, Charles S.
_q(Charles Stephen),
_d1936-
245 1 0 _aBasic feedback controls in biomedicine
_h[electronic resource] /
_cCharles S. Lessard.
260 _aSan Rafael, Calif. (1537 Fourth Street, San Rafael, CA 94901 USA) :
_bMorgan & Claypool Publishers,
_cc2009.
300 _a1 electronic text (xii, 209 p. : ill.) :
_bdigital file.
490 1 _aSynthesis lectures on biomedical engineering,
_x1930-0336 ;
_v# 27
538 _aMode of access: World Wide Web.
538 _aSystem requirements: Adobe Acrobat reader.
500 _aPart of: Synthesis digital library of engineering and computer science.
500 _aSeries from website.
504 _aIncludes bibliographical references.
505 0 _aElectrical system equations -- Kirchhoff 's laws -- A review of elements connected in series or in parallel -- Review of analogous quantities -- Review of source transformations -- Topological graph -- References -- Mechanical translation systems -- Example -- Example of a muscle model -- Summary -- References -- Mechanical rotational systems -- Example -- Gears -- Gear train example -- Electrical equivalent circuit -- Servomotors -- Armature control mode -- Field control mode -- References -- Thermal systems and systems representation -- Thermal systems -- Mercury thermometer example -- Example of the mercury thermometer with glass added -- System representation: the block diagram -- Block diagram example -- Control ratio or transfer function -- The characteristic equation -- Example block diagram of a motor control -- Transfer function equations for the servomotor example -- Signal flow graphs -- Signal flow diagram terminology -- Flow graph algebra -- Example of reduction -- References -- Characteristics and types of feedback control systems -- Stability of a linear system -- Routh's stability criterion -- Routhian array -- Example problem: Routhian array -- Solution -- Final solution -- Simplifying work -- Types of feedback systems -- Static error coefficients -- Steady-state error -- Example -- References -- Root locus -- Basic classical methods for analysis of control systems -- Root locus procedures -- Calibration of static loop sensitivity -- Rules for construction of the root locus -- Summary of root locus procedures -- Addition of poles and zeros -- References -- Frequency response analysis -- Steady-state frequency response -- Figures of merit used to measure system performance -- Relationship between the root locus and the frequency response -- Constant parameters on S plane -- Drawing the Bode plots -- Factors in log magnitude -- Deriving the transfer function from the log magnitude -- Summary -- References -- Stability and margins -- Nichols charts -- References -- Introduction to LabVIEW -- What is LabVIEW -- Environment -- Getting started -- Front panel -- Block diagram -- Controls and indicators -- Functions/controls palette -- Virtual instruments -- Data flow execution -- Running a VI -- LabVIEW resources -- Example finder -- Context help -- LabVIEW help -- Structures/programming constructs -- While loops -- For loops -- MathScript node -- Data structures -- Constants -- Arrays -- Clusters -- Graphs and charts -- Waveform graph -- Waveform chart -- What is the difference -- Summary -- Control design in LabVIEW -- Control design functions -- Continuous versus discrete models -- Model construction -- Constructing a transfer function graphically -- Constructing a transfer function with MathScript -- Model interconnection -- Series interconnection -- Parallel interconnection -- Feedback interconnection -- Model analysis -- Time response -- CD parametric time analysis -- Analyzing a step response -- Analyzing an impulse response -- Frequency response -- Review exercises -- Simulation in LabVIEW -- Simulation loop -- Creating a simulation loop -- Configuring a simulation -- Simulation parameters tab -- Timing parameters tab -- Generating simulation signals -- Displaying simulation output -- Implementing transfer functions -- LabVIEW control design and simulation exercise -- Construction of an open-loop block diagram -- Construction of closed-loop block diagram -- Reference -- LabVIEW controls tutorials -- Cardiac control -- Cardiac parameters -- Heart rate -- Stroke volume -- Cardiac output -- Contractility -- Preload and afterload -- Autonomic control -- Cardiac control diagram -- References -- Vestibular control system -- Physiology and anatomy -- Physiological basis for control -- Equilibrium and balance control system -- Interpretation of block diagram -- Block diagram of the vestibular control system -- Block diagram of the semicircular canal -- Block diagram of the otoliths -- Simulation of the control models in LabVIEW -- Transfer function of semicircular canals -- References -- Vestibulo-ocular control system -- Stimulus -- Response -- Normal performance -- Saccadic eye movements -- Smooth pursuit system -- Vestibulo-ocular reflex and vestibulo-collic (closed-loop VCR) reflexes -- Physiological pathways -- Special case -- Computational model -- Traditional model: Young and Stark model -- LabVIEW computational analysis with the Lisberger-Sejnowski VOR model -- Results of the LabVIEW analysis -- Summary -- References -- Gait and stance control system -- The hip -- The knee -- The ankle -- Overall system -- References -- Respiratory control system -- Pulmonary physiology -- Basics -- Method of ventilation control -- Gas laws -- Gas exchange at the alveoli -- Gas exchange in the lungs and tissues -- Gas exchange in the blood -- Conceptual model -- Mathematical model -- Additional assumptions -- Derivation of equations -- Inspiratory muscles -- Lungs -- Left heart -- Brain and tissue transport -- Body tissue -- Brain tissue -- Body and brain tissue venous return -- Central and peripheral chemoreceptors -- Right heart -- LabVIEW simulations -- References.
506 1 _aAbstract freely available; full-text restricted to subscribers or individual document purchasers.
510 0 _aCompendex
510 0 _aINSPEC
510 0 _aGoogle scholar
510 0 _aGoogle book search
520 _aThis textbook is intended for undergraduate students (juniors or seniors) in Biomedical Engineering, with the main goal of helping these students learn about classical control theory and its application in physiological systems. In addition, students should be able to apply the Laboratory Virtual Instrumentation Engineering Workbench (LabVIEW) Controls and Simulation Modules to mammalian physiology. The first four chapters review previous work on differential equations for electrical and mechanical systems. Chapters 5 through 8 present the general types and characteristics of feedback control systems and foot locus, frequency response, and analysis of stability and margins. Chapters 9 through 12 cover basic LabVIEW programming, the control module with its pallets, and the simulation module with its pallets. Chapters 13 through 17 present various physiological models with several LabVIEW control analyses. These chapters cover control of the heart (heart rate, stroke volume, and cardiac output), the vestibular system and its role in governing equilibrium and perceived orientation, vestibulo-ocular reflex in stabilizing an image on the surface of the retina during head movement, mechanical control models of human gait (walking movement), and the respiratory control model. The latter chapters (Chapters 13-17) combine details from my class lecture notes in regard to the application of LabVIEW control programming by the class to produce the control virtual instruments and graphical displays (root locus, Bode plots, and Nyquist plot). This textbook was developed in cooperation with National Instruments personnel.
530 _aAlso available in print.
588 _aTitle from PDF t.p. (viewed on March 9, 2009).
630 0 0 _aLabVIEW.
650 0 _aBiological control systems
_xMathematical models.
690 _aBasic feedback controls
690 _aClassical analysis
690 _aLabVIEW controls and simulation
690 _aMammalian physiological control systems
730 0 _aSynthesis digital library of engineering and computer science.
830 0 _aSynthesis lectures on biomedical engineering ;
_v# 27.
856 4 2 _3Abstract with links to resource
_uhttp://ieeexplore.ieee.org/servlet/opac?bknumber=6812788
999 _c561664
_d561664