Morphological measurements of the nasal and paranasal cavities were conducted to investigate their relevance to the acoustic properties of the human nasal tract. The magnetic resonance imaging (MRI) technique was used to measure the three-dimensional geometry of the vocal tract. The area function of the nasal tract was calculated for seven subjects based on data obtained during natural breathing. The entire vocal tract was measured for five subjects during sustained production of nasal consonants. A marked morphological difference was observed between our data and previously published data [A. S. House and K. N. Stevens, J. Speech Hear. Disord. 21, 218-232 (1956); G. Fant, Acoustic Theory of Speech Production (Mouton, The Hague, 1970), 2nd ed., p. 139] particularly in the middle portion of the nasal tract. Previous data derived from cadaver specimens showed a large cavity in the middle portion possibly due to an absent or dehydrated mucous membrane, while our data showed narrow passages due to thickly layered mucosa. It has been confirmed by an additional experiment that the wide cavity is reproducible by applying an adrenergic agent to the nasal mucosa. Transfer functions of the vocal tract and the nasal tract were calculated from measured data, and compared to spectra of real speech signals recorded subsequent to the MRI experiment. The results indicate that asymmetry between the two nasal passages can cause extra pole-zero pairs, and suggest that the paranasal cavities play an important role in shaping the spectral characteristics of human nasal sounds.