Abstract
Digital image correlation (DIC) systems have been used in many engineering fields to obtain surface full-field strain distribution. However, noise affects the accuracy and precision of the measurements due to many factors. The aim of this study was to find out how different filtering options; namely, simple mean filtering, Gaussian mean filtering and Gaussian low-pass filtering (LPF), reduce noise while maintaining the full-field information based on constant, linear and quadratic strain fields. Investigations are done in two steps. First, linear and quadratic strain fields with and without noise are simulated and projected to discrete measurement points which build up strain window sizes consisting of 6×5, 12×11, and 26×17 points. Optimal filter sizes are computed for each filter strategy, strain field type, and strain windows size, with minimal impairment of the signal information. Second, these filter sizes are used to filter full-field strain distributions of steel samples under tensile tests by using an ARAMIS DIC system to show their practical applicability. Results for the first part show that for a typical 12×11 strain window, simple mean filtering achieves an error reduction of 66–69%, Gaussian mean filtering of 72–75%, and Gaussian LPF of 66–69%. If optimized filters are used for DIC measurements on steel samples, the total strain error can be reduced from initial 240−300 μstrain to 100–150 μstrain. In conclusion, the noise-floor of DIC signals is considerable and the preferable filters were a simple mean with s*¯ = 2, a Gaussian mean with σ*¯ = 1.7, and a Gaussian LPF with D0*¯ = 2.5 in the examined cases.
Highlights
Digital image correlation (DIC) was introduced as an alternative method for measuring strains in the 1980s [1]
The primary objective of this study is to show how the noise can be reduced for different strain window sizes and strain field types, using three practical filters and how the total error changes when filter parameters change
DIC offers a method for capturing full-field deformation on the surface of the samples, regardless of their size, shape or material
Summary
Digital image correlation (DIC) was introduced as an alternative method for measuring strains in the 1980s [1]. It has the potential to measure surface strain optically by capturing images of the sample during deformation and thereby overcoming limitations such as attaching strain gauges (SGs) to the sample or the size of measured area. For tracking the displacement on the surface of the sample using a DIC system, the surface of test samples has to be sprayed with random speckle patterns. The surface is divided into facets of pixels, each facet has unique pixel patterns, and the centers of these facets are known as measurement points. The displacement and strain are calculated for the measurement points of each facet between the deformed and non-deformed images [1,2,3]. For further details on the working principle of DIC, please refer to Appendix A
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