Respiratory flow profiles have been of interest as an output of the respira
tory controller. In determining average flow profiles, however, previous me
thods that align individual breaths in the time domain are susceptible to d
istortions caused by the great variability, both between breaths and within
breaths. We aimed to develop a method for determining typical flow profile
s that circumvents such distortions. Our method aligns different breaths by
phase of respiratory cycle, which is defined as the angle associated with
the point on the normalized flow-volume diagram (a phase-plane plot). Over
a number of breaths, median values for flow, volume, and elapsed time from
the start of the breath at each phase angle are determined. Because these e
stimates are mutually semi-independent and in general violate the laws of m
ass balance, an adjustment was performed such that the volume was precisely
the time integral of the flow. The method produced typical flow profiles w
ith characteristics that were significantly closer to the mean values obtai
ned from the individual cycles than those obtained by the technique of Benc
hetrit and co-workers (Benchetrit G, Shea SA, Dinh TP, Bodocco S, Baconnier
P, and Gut A, Respir Physiol 75: 199-210, 1989), which reconstructs the ty
pical flow profile from Fourier coefficients.