Pressure correction schemes and the use of the Wiener deconvolution method in pneumatic systems with short tubes.

Experiments are conducted to evaluate the ability of various schemes to correct for pressure distortion caused by a finite tubing length between the pressure tap and the transducer. This study focuses on relatively short tubes, such as those encountered in multi-hole probes. Experimentally determined dynamic response is compared to the analytical model of Berg and Tijdeman with and without the Wiener filter. Bench-top experiments show that, for pneumatic systems with relatively short tubes, the addition of the Wiener filter carries no advantage over the Berg and Tijdeman model. The true advantage of the Wiener deconvolution method is observed for pressure tubes longer than ∼150 mm. Finally, the mean axial velocity and three Reynolds stress distributions from three correction schemes are compared to particle image velocimetry (PIV) results in a shear flow experiment. The statistical results ascertain the advantage of the Berg and Tijdeman and the Wiener deconvolution method over the generally noise-dominated inverse transfer function method. [ABSTRACT FROM AUTHOR]