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In modern very large scale integration manufacturing processes, dummy fills are widely used to adjust local metal density in order to improve layout uniformity and yield optimization. However, the introduction of a large amount of dummy features also affects wire electrical properties. In this paper, we propose the first coupling-constrained dummy-fill analysis algorithm which identifies feasible locations for dummy fills such that the fill-induced coupling capacitance can be bounded within the given coupling threshold of each wire segment. A speedup approach is presented based on the cache concept. The algorithm also makes efforts to maximize ground dummy fills, which are more robust and predictable. The output of the algorithm can be treated as the upper bound for dummy-fill insertion, and it can be easily adopted in density models to guide dummy-fill insertion without disturbing the existing design.