We report on the implications of the peak in the cosmic star formation rate
(SFR) at redshift z approximate to 1.5 for the resulting population of low
-mass X-ray binaries (LMXBs) and for that of their descendants, the millise
cond radio pulsars (MRPs). Since the evolutionary timescales of LMXBs, thei
r progenitors, and their descendants are thought be significant fractions o
f the time interval between the SFR peak and the present epoch, there is a
lag in the turn-on of the LMXB population, with the peak activity occurring
at z similar to 0.5-1. The peak in the MRP population is delayed further,
occurring at z less than or similar to 0.5. We show that the discrepancy be
tween the birthrate of LMXBs and the birthrate of MRPs. found under the ass
umption of a steady state SFR, can be resolved for the population as a whol
e when the effects of a time-variable SFR are included. A discrepancy may p
ersist for LMXBs with short orbital periods, although a detailed population
synthesis will be required to confirm this. Furthermore, since the integra
ted X-ray luminosity distribution of normal galaxies is dominated by X-ray
binaries, it should show strong luminosity evolution with redshift. In addi
tion to an enhancement near the peak (z approximate to 1.5) of the SFR due
to the prompt turn-on of the relatively short-lived massive X-ray binaries
and young supernova remnants, we predict a second enhancement by a factor o
f similar to 10 at a redshift between similar to 0.5 and similar to 1 due t
o the delayed turn-on of the LMXB population. Deep X-ray observations of ga
laxies out to z approximate to 1 by the Advanced X-Ray Astrophysics Facilit
y will be able to observe this enhancement and, by determining its shape as
a function of redshift, will provide an important new method for constrain
ing evolutionary models of X-ray binaries.