selfish agent, who is only interested in minimizing its own cost,
which is defined as the total load on the machine that its job is
assigned to. We consider the objective of maximizing the minimum load
(cover) over the machines.
Unlike the regular makespan minimization problem, which was extensively
studied in a game theoretic context, this problem has not been
considered in this setting before.
We study the price of anarchy (\poa) and the price of stability (\pos).
We show that on related machines, both these values are unbounded.
We then focus on identical machines. We show that the $\pos$ is 1, and we derive tight bounds on the $\poa$ for $m\leq6$ and nearly tight bounds for general $m$. In particular, we show that the $\poa$ is at least 1.691 for larger $m$ and at most 1.7. Hence, surprisingly, the
$\poa$ is less than the $\poa$ for the makespan problem, which is 2.
To achieve the upper bound of 1.7, we make an unusual use of weighting
functions.
Finally, in contrast we show that the mixed $\poa$ grows exponentially with
$m$ for this problem, although it is only $\Theta(\log m/\log \log m)$ for the
makespan.