Solar acoustic signals constructed with the technique of acoustic imaging c
ontain both intensity and phase information. The phase of constructed signa
ls can be studied by computing the cross-correlation function between time
series constructed with ingoing and outgoing waves. The envelope peak of th
e cross-correlation function provides information about wave travel time, a
ssociated with the group velocity along the wave path. The phase time of th
e cross-correlation function provides information about phase changes along
the wave path, including the phase change at boundaries of the mode cavity
and boundaries of flux tubes. We study the active region NOAA 7978 using t
he data taken with the Michelson Doppler Imager (MDI) instrument. We constr
uct two-dimensional phase-shift maps and envelope-shift maps of the active
region at the surface by determining the phase time and envelope time of th
e cross-correlation function at each point. Both phase time and envelope ti
me in magnetic regions are smaller than those in the quiet Sun. The phase s
hift and envelope shift at each point are computed by subtracting the avera
ge values in the quiet Sun. The envelope shift is greater than the phase sh
ift by about 2.5 minutes inside sunspots. Both the envelope shift and the p
hase shift in sunspots increase approximately linearly with frequency. The
difference between the envelope shift and phase shift is the same at differ
ent frequencies. There is evidence for an additional phase shift in sunspot
s relative to plages. We discuss inferences about the structure of sunspots
from these phenomena.