C. R. Coggrave scite author profile

We present results from numerical simulations of a dynamic phase-shifting speckle interferometer used in the presence of mechanical vibrations. The simulation is based on a detailed mathematical model of the system, which is used to predict the expected frequency response of the rms measurement error, in the time-varying phase difference maps, as a result of vibration. The performance of different phase-shifting algorithms is studied over a range of vibrational frequencies. Phase-difference evaluation is performed by means of temporal phase shifting and temporal phase unwrapping. It is demonstrated that longer sampling windows and higher framing rates are preferred in order to reduce the phase-change error that is due to vibration. A numerical criterion for an upper limit on the length of time window for the phase-shifting algorithm is also proposed. The numerical results are finally compared with experimental data, acquired with a phase-shifting speckle interferometer of 1000 frames/s.

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High-speed surface profilometer based on a spatial light modulator and pipeline image processor

Coggrave

1999

Opt. Eng

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Shape and displacement measurement of discontinuous surfaces by combining fringe projection and digital image correlation

et al. 2011

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We describe how a shape-measurement system (SMS) based on fringe projection can be combined with a two-dimensional digital image correlation (DIC) technique to accurately measure both surface profile and displacement fields at the same time. Whereas the measurement of all three displacement components by traditional DIC requires the use of at least two cameras, the approach presented here provides the full three-dimensional (3-D) displacement field from a single-camera, singleprojector SMS with no additional hardware requirements. Furthermore, the single-pixel spatial resolution of the fringe projection technique can be exploited to prevent the correlation peak-splitting phenomenon that occurs when a DIC subimage straddles a global geometrical discontinuity. Thus, unlike traditional 3-D DIC techniques, the proposed method can measure displacement fields on discontinuous surfaces as easily as on smooth ones. Details of the algorithm are given together with experimental results of a rigid-body translation test. Measurements made during a routine fatigue test on a part of a wing panel are also presented. C 2011 Society of Photo-Optical Instrumentation Engineers (SPIE).

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Fast Hough transform for automated detection of spheres in three-dimensional point clouds

Coggrave¹

2007

Opt. Eng

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C. R. Coggrave

Optimization of a shape measurement system based on spatial light modulators

Vibration-induced phase errors in high-speed phase-shifting speckle-pattern interferometry

High-speed surface profilometer based on a spatial light modulator and pipeline image processor

Shape and displacement measurement of discontinuous surfaces by combining fringe projection and digital image correlation

Fast Hough transform for automated detection of spheres in three-dimensional point clouds

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