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Measurements of Strain01:27

Measurements of Strain

Strain quantifies the deformation of a material under force, typically measured as normal strain, which represents the change in length when compared with the original length. Electrical strain gauges are used for enhanced accuracy. These devices consist of a conductive wire mounted on a paper backing that adheres to the material's surface. These gauges operate on the piezoresistive effect, where the wire's electrical resistance changes in response to mechanical deformation. The strain gauge...
Design Example: Strain Gauge Bridge or Wheatstone Bridge01:15

Design Example: Strain Gauge Bridge or Wheatstone Bridge

The utilization of strain gauges as transducers for converting mechanical strain into electrical signals is a common practice in various engineering applications. These strain gauges are frequently integrated into Wheatstone bridge circuits to accurately measure parameters such as force or pressure. Within this context, each element within the circuit exhibits a resistance that undergoes subtle variations when subjected to mechanical strain. The primary objective is to convert minuscule...
Strain and Elastic Modulus01:15

Strain and Elastic Modulus

The quantity that describes the deformation of a body under stress is known as strain. Strain is given as a fractional change in either length, volume, or geometry under tensile, volume (also known as bulk), or shear stress, respectively, and is a dimensionless quantity. The strain experienced by a body under tensile or compressive stress is called tensile or compressive strain, respectively. In contrast, the strain experienced under bulk stress and shear stress is known as volume and shear...
Elastic Strain Energy for Shearing Stresses01:20

Elastic Strain Energy for Shearing Stresses

As discussed in previous lessons, strain energy in a material is the energy stored when it is elastically deformed, a concept crucial in materials science and mechanical engineering. This energy results from the internal work done against the cohesive forces within the material. When a material undergoes shearing stress and corresponding shearing strain, the strain energy density, which is the energy stored per unit volume, is calculated. Within the elastic limit, where the stress is...
True Stress and True Strain01:28

True Stress and True Strain

Engineering stress is calculated as the load divided by the original, undeformed cross-sectional area. It approximates a material under load. This approximation is especially relevant post-yield in ductile materials. Though engineering stress-strain diagrams are often used for their convenience and accessibility, they can sometimes fall short in accuracy, particularly when dealing with large strain values.
In contrast, true stress offers a more precise portrayal. It is computed by dividing the...
Elastic Strain Energy for Normal Stresses01:22

Elastic Strain Energy for Normal Stresses

Strain energy quantifies the energy stored within a material due to deformation under loading conditions, a fundamental concept in materials science and engineering. The strain energy can be modeled when a material is subjected to axial loading with uniformly distributed stress. In this scenario, the stress experienced by the material is the internal force divided by the cross-sectional area, and the strain induced is directly proportional to this stress through the modulus of elasticity.
If...

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Related Experiment Video

Updated: Jul 8, 2026

A Random-displacement Measurement by Combining a Magnetic Scale and Two Fiber Bragg Gratings
08:23

A Random-displacement Measurement by Combining a Magnetic Scale and Two Fiber Bragg Gratings

Published on: September 30, 2019

Wide-range fiber-optic strain sensor.

D C Marvin1, N A Ives

  • 1Aerospace Corporation, P.O. Box 92957, Los Angeles, California 90009, USA.

Applied Optics
|December 1, 1984
PubMed
Summary
This summary is machine-generated.

A novel optical fiber strain sensor uses a roller chain to create constant bends, offering adjustable sensitivity and a linear response. This design provides a wide measurement range unlike traditional microbend sensors.

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Last Updated: Jul 8, 2026

A Random-displacement Measurement by Combining a Magnetic Scale and Two Fiber Bragg Gratings
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Published on: September 30, 2019

Production of a Strain-Measuring Device with an Improved 3D Printer
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Published on: January 30, 2020

Fiber Optic Distributed Sensors for High-resolution Temperature Field Mapping
09:48

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Published on: November 7, 2016

Area of Science:

  • Optoelectronics
  • Fiber optic sensing
  • Mechanical engineering

Background:

  • Microbend fiber optic sensors commonly use corrugated plates for sinusoidal bends.
  • Existing designs have limitations in sensitivity adjustment and linearity.
  • Optical fiber sensors are valuable for strain measurement due to their remote sensing capabilities.

Purpose of the Study:

  • To report a novel wide-range strain sensor utilizing optical fiber.
  • To introduce a new method for imposing bends on optical fibers for sensing applications.
  • To achieve adjustable sensitivity and a linear calibration curve in an optical fiber strain sensor.

Main Methods:

  • An optical fiber was used as the transducing element.
  • A roller chain mechanism was employed to impose constant curvature bends on the optical fiber.
  • The sensor's response was characterized for strain measurement.

Main Results:

  • The proposed sensor demonstrated a wide measurement range.
  • The use of a roller chain allowed for a wide range of sensitivity adjustment.
  • A linear calibration curve was achieved, indicating reliable performance.

Conclusions:

  • The roller chain-based optical fiber sensor offers a significant improvement over traditional microbend sensors.
  • This new design provides a versatile and linear strain sensing solution.
  • The sensor is suitable for applications requiring wide-range and adjustable strain measurement.