An electrical analog frequency filter network demonstrated that pressure wave distortion in arteries can be explained by resonant frequency and damping coefficients dependent on arterial properties.
An electrical analog model demonstrates that arterial pressure wave distortion can be explained by resonant frequency and damping coefficients related to the physical properties of the artery.
The large arteries may be expected to respond to a central pulse wave as a resonant system and the pressure pulse can be resolved into a series of pure sinusoidal waves. Therefore, a frequency filter network was designed which could duplicate the resonant frequency and damping coefficient of a segment of artery by proper adjustment of the circuit constants. Data are presented which support the concept that much of the distortion of a pressure wave in its transmission down an artery can be explained in terms of a resonant frequency and damping coefficient, and that these variables in turn arc dependent upon physical properties of the segment of artery transmitting the wave.
Homer R. Warner (Tue,) conducted a other in Pressure wave distortion by arterial walls. Electrical analog (frequency filter network) was evaluated on Pressure wave distortion. An electrical analog frequency filter network demonstrated that pressure wave distortion in arteries can be explained by resonant frequency and damping coefficients dependent on arterial properties.
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