In this paper the problem of scheduling of jobs on parallel machines under incompatibility relation is considered. In this model a binary relation between jobs is given and no two jobs that are in the relation can be scheduled on the same machine. In particular, we consider job scheduling under incompatibility relation forming bipartite graphs, under makespan optimality criterion, on uniform and unrelated machines. We show that no algorithm can achieve a good approximation ratio for uniform machines, even for a case of unit time jobs, under $P eq NP$. We also provide an approximation algorithm that achieves the best possible approximation ratio, even for the case of jobs of arbitrary lengths $p_j$, under the same assumption. Precisely, we present an $O(n^{1/2-epsilon})$ inapproximability bound, for any $epsilon > 0$; and $sqrt{p_{sum}}$-approximation algorithm, respectively. To enrich the analysis, bipartite graphs generated randomly according to Gilberts model $mathcal{G}_{n,n,p(n)}$ are considered. For a broad class of $p(n)$ functions we show that there exists an algorithm producing a schedule with makespan almost surely at most twice the optimum. Due to our knowledge, this is the first study of randomly generated graphs in the context of scheduling in the considered model. For unrelated machines, an FPTAS for $R2|G = bipartite|C_{max}$ is provided. We also show that there is no algorithm of approximation ratio $O(n^bp_{max}^{1-epsilon})$, even for $Rm|G = bipartite|C_{max}$ for $m ge 3$ and any $epsilon > 0$, $b > 0$, unless $P = NP$.
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