Error analysis of laser interferometric system for measuring radius of curvature

Ahmed, Ammar; Amer, Mohamed; Nada, Nadra

doi:10.1007/s12596-023-01269-9

Cited by 4 publications

(3 citation statements)

References 35 publications

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“…Error analysis for an interferometer-based calibration system is not a novel issue [21][22][23][24]. It is important for calibration systems, especially for economical systems, because commercial interferometers and motor stages vary widely in type, cost, and performance.…”

Section: Error Analysismentioning

confidence: 99%

Error Analysis of an Economical On-Site Calibration System for Linear Optical Encoders

Huang,

Su,

Chang

et al. 2024

Metrology

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A calibration system was designed to evaluate the accuracy of linear optical encoders at the micron level in a fast and economical manner. The system uses a commercial interferometer and motor stage as the calibrator and moving platform. Error analysis is necessary to prove the effectiveness and identify areas for optimization. A fixture was designed for the scale and interferometer target to meet the Abbe principle. A five-degree-of-freedom manual stage was utilized to adjust the reading head in optimal or suboptimal working conditions, such as working distance, offset, and angular misalignment. The results indicate that the calibration system has an accuracy of ±2.2 μm. The geometric errors of the calibration system, including mounting errors and non-ideal motions, are analyzed in detail. The system could be an inexpensive solution for encoder manufacturers and customers to calibrate a linear optical encoder or test its performance.

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Section: Error Analysismentioning

confidence: 99%

Error Analysis of an Economical On-Site Calibration System for Linear Optical Encoders

Huang,

Su,

Chang

et al. 2024

Metrology

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“…[1,2] They offer angular detection with high resolution, making them an excellent candidate for integration with curvature-sensitive applications such as soft-bodied robots [3,4] and optical fibers. [5] External curvature sensors often rely on interferometry [6][7][8] to detect the interference fringes from the object and a reference beam, making them suitable for non-contact measurement methods. However, they typically require high beam coherence, which limits their range, precise alignment, and time-consuming measurements.…”

Section: Introductionmentioning

confidence: 99%

Self‐Calibrated Flexible Holographic Curvature Sensor

Xiao,

Plaskocinski,

Biabanifard

et al. 2024

Adv Materials Technologies

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Optical curvature sensors find regular use in deformation analysis, typically requiring pre‐calibration and post‐processing of the gathered data. In this work, a self‐calibrated curvature sensor based on flexible holographic metasurfaces operating in the visible range is presented. In contrast to existing solutions, the sensor can be fabricated independently from the target objects and provides an immediate readout of their curvature. The sensor consists of distinct patterned areas that create images of a reference scale and of a position indicator, which shift with respect to each other, as the metasurface is deformed. The results of this sensor are validated with an external calibration and critically discuss the types of deformations that the sensor can detect. This feature makes the sensor particularly attractive for applications where real‐time curvature monitoring is essential, such as in robotics, biomechanics, and structural health monitoring.

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“…Surface irregularities are a significant problem in characterizing the qualities of spherical surfaces; they appear as wrinkles, dents, plastic deformation, and warps [12]. Therefore, much valuable data is gained by measuring surface irregularities, such as wear resistance, sealing, friction, lubricant retention, contact ability, fatigue, performance of optical systems, and the accuracy of the radius of curvature [13][14] [15]. The surface irregularities can be measured by; contact and non-contact methods.…”

Section: Introductionmentioning

confidence: 99%

Accurate Measurement of Surface Irregularities for a Standard Sphere Using Fizeau Laser Interferometer

Saleh,

Amer,

Nada

2023

Journal of Scientific Research in Science

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Spherical surfaces are essential components in optical systems for different applications. Also, standard spheres are typically employed to calibrate dimensional and mass-measuring instruments. Therefore, measuring and eliminating the surface irregularities of these spheres represents a challenge for modern industries. Surface irregularities can be measured by either the contact method (as stylus profilometers) or the non-contact method (as interferometers). The Fizeau laser interferometer (GPI-XP, Zygo Co.) is typically used to accurately measure surface irregularities for flat surfaces, lenses, and mirrors of 102 mm diameter, and it is not prepared for testing heavy spheres. This work presents a modification for the interferometric system to expand its capability for testing spheres of diameters up to 145 mm and masses up to 2 kg. Also, the modification provides automatic rotation for the tested surfaces (an electric rotating platform) to avoid the disadvantages of manual rotation (a tweezer). At different rotation angles, the measurements are performed on a mass-standard silicon sphere (SiScKg-02-d, PTB Inst.). The average measured value of the surface irregularities is 43.9 nm, with an improved repeatability of 2.8 nm and a minimized measurement uncertainty of ±6.8 nm. The evaluation of the uncertainty budget is also investigated in this study.

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Error analysis of laser interferometric system for measuring radius of curvature

Cited by 4 publications

References 35 publications

Error Analysis of an Economical On-Site Calibration System for Linear Optical Encoders

Error Analysis of an Economical On-Site Calibration System for Linear Optical Encoders

Self‐Calibrated Flexible Holographic Curvature Sensor

Accurate Measurement of Surface Irregularities for a Standard Sphere Using Fizeau Laser Interferometer

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