Earthquake sources are commonly viewed as shear dislocations. This imposes
distinct limitations on what source parameters can be realistically determi
ned from radiated shear-wave spectra. First, the slip velocity on the fault
is the real parameter that controls the strength of the high-frequency rad
iation; it can be directly determined from acceleration spectra by fitting
their high-frequency level. Second, the relationship between corner frequen
cy of the spectrum and the radius of the source is fundamentally unclear. A
s a result, the source dimensions cannot be accurately determined from the
spectra; such an estimate would be as accurate as any other informed guess.
Third, the stress drop only serves as a proxy for the source radius in the
relationship between the radius and the corner frequency; it thus cannot b
e reliably determined from the spectra. The quantity usually obtained from
the spectra and referred to as the stress drop is a poorly defined paramete
r that may bear little relevance to the actual stresses acting on faults. T
his parameter has little meaning unless converted to the maximum slip veloc
ity, which is the only quantity that can be accurately determined from the
spectra. The typical value of stress drop of 100 bars, established from the
spectra of California events, may imply that the typical slip velocities h
ave been on the order of 0.5 m/sec, although it is more accurate to determi
ne slip velocities directly from the spectra.