SQUID-based magnetic microscopy involves scanning a sample closely pas
t a low-noise SQUID. With the SQUID held in a flux-locked loop, a comp
uter records the feedback output as a function of sample position and
converts the resulting data into a false color image of magnetic field
strength. Present systems have achieved spatial resolution down to ab
out 5 mu m and flux resolution down to about 1 mu Phi(o)/Hz(1/2). They
have been used to study the pairing symmetry of the high-T-c supercon
ductors, for high-frequency imaging, and for a variety of applications
related studies. Recently, microscopes have also been developed for h
igh resolution magnetic imaging of room-temperature samples. We briefl
y describe the design, operation, and capabilities of these systems.