We consider the problem of
scheduling in a single-hop switched network with a mix of heavy-tailed and
light-tailed traffic and analyze the impact of heavy-tailed traffic on the
performance of Max-Weight scheduling. As a performance metric, we use the delay
stability of traffic flows: A traffic flow is delay-stable if its expected
steady-state delay is finite and delay-unstable otherwise. First, we show that
a heavy-tailed traffic flow is delay-unstable under any scheduling policy.
Then, we focus on the celebrated Max-Weight scheduling policy and show that a
light-tailed flow that conflicts with a heavy-tailed flow is also
delay-unstable. This is true irrespective of the rate or the tail distribution
of the light-tailed flow or other scheduling constraints in the network.
Surprisingly, we show that a light-tailed flow can become delay-unstable, even
when it does not conflict with heavy-tailed traffic. Delay stability in this
case may depend on the rate of the light-tailed flow. Finally, we turn our
attention to the class of Max-Weight-α scheduling policies. We show that if the
α-parameters are chosen suitably, then the sum of the α-moments of the
steady-state queue lengths is finite. We provide an explicit upper bound for
the latter quantity, from which we derive results related to the delay
stability of traffic flows, and the scaling of moments of steady-state queue
lengths with traffic intensity.
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