Abstract
We study a temperature-aware scheduling problem aiming in maximizing the throughput of a set of unit-length jobs, each one having its own heat contribution, on a single processor operating under a strict temperature threshold. Following a simplified model for the processor’s thermal behavior, proposed by Chrobak et al.[9], we analyze the approximation factor of the natural CoolestFirst scheduling algorithm for jobs with common release dates and deadlines. We first prove a \(\frac{k}{k+1}\) factor, where k depends on a partition of the jobs according to their heat contributions. Next, we refine our partition and provide a linear program that shows a lower bound of 0.72 on the approximation factor.
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This work was partially supported by the Basic Research Funding Program of the Athens University of Economics and Business (C. Dürr, I. Milis, G. Zois) and by the European Social Fund and Greek national resources under the programs HERACLEITUS II (G. Zois) and THALES-ALGONOW (I. Milis).
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Dürr, C., Milis, I., Robert, J., Zois, G. (2013). Approximating the Throughput by Coolest First Scheduling. In: Erlebach, T., Persiano, G. (eds) Approximation and Online Algorithms. WAOA 2012. Lecture Notes in Computer Science, vol 7846. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-38016-7_16
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DOI: https://doi.org/10.1007/978-3-642-38016-7_16
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