T at a given time for a
given source in the Galactic bulge towards Baade's window reaches 100%
for a threshold of T =
0.7 µas, while this probability is ~ 2% for T =
5 µas. However, this centroid shift does not
vary much during the time in which a typical photometric
microlensing event differs from baseline. So astrometric follow-ups
(e.g. with SIM) are not expected to be disturbed by the
statistical astrometric microlensing due to disk stars, so that it is
possible to infer additional information about the nature of the lens
that caused the photometric event, as suggested. The probability to
observe astrometric microlensing events within the Galaxy turns out to
be large compared to photometric microlensing events. The probability
to see a variation by more than 5 µas within one
year and to reach the closest angular approach between lens and source
is ~ 10-4 for a bulge star towards
Baade's window, while this reduces to ~6 × 10-6 for a
direction perpendicular to the Galactic plane. For the upcoming
mission GAIA, we expect ~1000 of the observed stars to show a
detectable astrometric microlensing signal within its 5 year lifetime.
These events can be used to determine accurate masses of the lenses,
and to derive the mass and the scale parameters (length and height) of
the Galactic disk.