This report presents the Taguchi method, used to investigate the planning of large-scale passive harmonic filters. Orthogonal arrays are widely employed in experimental processes for solving practical problems encountered because such arrays are geometrically balanced in their coverage of the experimental region after only a few representative experiments have been implemented. The signal-to-noise ratio(S/N) is employed to investigate the robust design of harmonic filters. In the design of harmonic filters, some uncertainties should be considered. Noise factors have been considered to cause filter parameter detuning, loading uncertainty and changing of system impedances. Our design approach has been applied to harmonic mitigation problems for a chemical plant, where three large-size 6-pulse rectifiers are installed. The purposes are to minimize the total demand distortion of harmonic currents and total harmonic distortion of voltages. Filters loss, reactive power compensation, and constraints of individual harmonics should are also considered. Additional results related to the Taguchi method are also reported and discussed as well.