Basic Feedback Controls in Biomedicine
作者: Charles S. Lessard
DOI:
关键词:
摘要: This textbook is intended for undergraduate students (juniors or seniors) in Biomedical Engineering, with the main goal of helping these learn about classical control theory and its application physiological systems. In addition, should be able to apply Laboratory Virtual Instrumentation Engineering Workbench (LabVIEW) Controls Simulation Modules mammalian physiology. The first four chapters review previous work on differential equations electrical mechanical Chapters 5 through 8 present general types characteristics feedback systems foot locus, frequency response, analysis stability margins. 9 12 cover basic LabVIEW programming, module pallets, simulation pallets. 13 17 various models several analyses. These heart (heart rate, stroke volume, cardiac output), vestibular system role governing equilibrium perceived orientation, vestibulo-ocular reflex stabilizing an image surface retina during head movement, human gait (walking movement), respiratory model. latter (Chapters 13-17) combine details from my class lecture notes regard programming by produce virtual instruments graphical displays (root Bode plots, Nyquist plot). was developed cooperation National Instruments personnel. Table Contents: Electrical System Equations / Mechanical Translation Systems Rotational Thermal Representation Characteristics Types Feedback Control Root Locus Frequency Response Analysis Stability Margins Introduction Design LabVI W Exercise Cardiac Vestibular Vestibulo-Ocular Gait Stance Respiratory
morganclaypool.com
amazon.com参考文章(20)
G. Muscato, G. Spampinato, Kinematical model and control architecture for a human inspired five DOF robotic leg Mechatronics. ,vol. 17, pp. 45- 63 ,(2007) , 10.1016/J.MECHATRONICS.2006.05.003
B. Deswysen, A. A. Charlier, M. Gevers, Quantitative evaluation of the systemic arterial bed by parameter estimation of a simple model. Medical & Biological Engineering & Computing. ,vol. 18, pp. 153- 166 ,(1980) , 10.1007/BF02443290
Zbigniew L. Topor, Konstantinon Vasilakos, Magdy Younes, John E. Remmers, Model based analysis of sleep disordered breathing in congestive heart failure. Respiratory Physiology & Neurobiology. ,vol. 155, pp. 82- 92 ,(2007) , 10.1016/J.RESP.2006.04.016
Henry N. Po, N. M. Senozan, The Henderson-Hasselbalch Equation: Its History and Limitations Journal of Chemical Education. ,vol. 78, pp. 1499- ,(2001) , 10.1021/ED078P1499
Mauro Ursino, Elisa Magosso, A theoretical analysis of the carotid body chemoreceptor response to O2 and CO2 pressure changes. Respiratory Physiology & Neurobiology. ,vol. 130, pp. 99- 110 ,(2002) , 10.1016/S0034-5687(01)00335-8
A. Buizza, R. Schmid, Visual-vestibular interaction in the control of eye movement: Mathematical modelling and computer simulation Biological Cybernetics. ,vol. 43, pp. 209- 223 ,(1982) , 10.1007/BF00319980
Robert de Levie, The Henderson-Hasselbalch Equation: Its History and Limitations Journal of Chemical Education. ,vol. 80, pp. 146- ,(2003) , 10.1021/ED080P146
S.G. Lisberger, The neural basis for motor learning in the vestibulo-ocular reflex in monkeys Trends in Neurosciences. ,vol. 11, pp. 147- 152 ,(1988) , 10.1016/0166-2236(88)90140-3
Jean-Luc Elghozi, Claude Julien, Sympathetic control of short‐term heart rate variability and its pharmacological modulation Fundamental & Clinical Pharmacology. ,vol. 21, pp. 337- 347 ,(2007) , 10.1111/J.1472-8206.2007.00502.X
L. R. Young, L. Stark, A Discrete Model for Eye Tracking Movements IEEE Transactions on Military Electronics. ,vol. 7, pp. 113- 115 ,(1963) , 10.1109/TME.1963.4323060