A method that couples output from a hot-wire anemometer with that of a
microphone to reduce flow-induced pseudonoise from the microphone sig
nal was developed. In these experiments, a microphone and a hot-wire s
ensor were placed in a well-defined low-speed turbulent flow in a rect
angular duct. Controlled acoustic noise, both random and time harmonic
, was superimposed on the flow noise by placing a speaker source close
to the entrance of the duct. Detailed studies of the coherence betwee
n the hot-wire and microphone signals in the presence of flow and acou
stic noise indicated that the proper combination of the two signals co
uld reduce the turbulence noise contamination in the microphone signal
, Subsequent tests demonstrated that using an adaptive least-mean-squa
re algorithm to filter the hot-wire signal before subtracting it from
the microphone signal produced broadband flow noise attenuation on the
order of 20 dB at frequencies below 100 Hz and spectra that approache
d those of the uncontaminated microphone signal. Moreover, the resulti
ng ''hot-mic'' signal retains the acoustic pressure of interest, makin
g it an ideal sensor for use in active noise control applications wher
e the sensing or error microphone must be placed in a flowfield.