This paper presents the results of nonlinear dynamic analyses carried out o
n ductile coupled shear walls (CSWs) to investigate the seismic shear deman
d on wall segments. The objectives of the present study were to evaluate th
e dynamic amplification and establish a code-format force reduction factor
for shear, applicable in Canada. The study considered three Canadian seismi
c zones (4, 5, and 6), five numbers of storeys (6, 10, 15, 20, and 30), thr
ee degrees of coupling (low, medium, and high), and 10 historical earthquak
e records encompassing a broad range of frequency contents. Overall, 450 an
alyses were performed. Results indicate that the New Zealand amplification
factor beta(v) presently used in Canada overestimates the dynamic amplifica
tion. Additionally, the use of the overstrength factor for shear gamma(p) f
or tension walls may underestimate their shear resistance and result in a s
hear failure. Conversely, the use of gamma p for compression walls provided
a reasonable factor of safety. Finally, for the shear design of CSWs, two
alternative approaches are suggested. The first involves the use of a force
reduction factor for shear, R-v, including the dynamic amplification facto
r gamma(d) and the overstrength factor gamma(p) as follows: R-v = 2.0 for Z
(a) > Z(v), R-v = 1.0 for Z(a) < Z(v), and R-v = 1.3 for Z(a) = Z(v), where
Z(a) and Z(v) are acceleration- and velocity-related zonal identifiers. Th
e second approach implies the use of the overstrength factor gamma(p) of th
e compression wall for both walls of CSWs and beta(v) = 1.0.