2D Digital Image Correlation (DIC)

Obtain valuable additional information on specimen behavior together with standard strain measurement!
ZwickRoell’s DIC makes local strains visible in 2D over the entire specimen surface.

Description Examples Difference 2D / 3D Specimen preparation Procedure Analysis tools Testing machines

What is 2D digital image correlation?

2D digital image correlation visualizes deformations and strain over the entire visible specimen surface. The non-contact videoXtens extensometer records image series during the test, compares image by image, and calculates the displacement in a pre-defined facet field, where each facet includes a specified number of camera pixels. This data is used to create two-dimensional color strain maps, which allow you to analyze the specimen behavior at a glance.

DIC - Digital Image Correlation

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Examples of 2D DIC analyses

ZwickRoell 2D digital image correlation (abbr.: DIC) offers you different DIC analysis options, including:

Color displays of specimen behavior provide indications of inhomogeneous local strain and other special features.
Local strains can be determined via the cutting line and point measurements, as well as via virtual strain gauges and virtual gauge lengths.
You can also analyze components, complex specimens with notches or non-homogeneous materials.
Verify your live strain measurement results.
Errors in the test arrangement, such as inaccurate specimen alignment quickly become visible.

Specific application examples:

The use of cost-efficient virtual strain gauges for shear tests with notched specimens to ASTM D5379 and ASTM D7078 (link to video)
Open-hole tensile (OHT) strength test to ASTM D5766 with determination of the stress concentration near the hole
FE (finite element) model validation: Comparison of the displacement and strain field through the FE simulation
Determination of stress-strain curves (true, technical)
Evaluation of specimen failure through assessment of the point of fracture, for example through determination of a local strain maximum at the point of fracture
Verification of the heterogeneity of the material and identification of local failure

You have a wide selection of analytical tools and diagram displays at your disposal for the analysis process.

Difference between 2D and 3D digital image correlation

Many applications do not require 3D DIC. Two-dimensional DIC analysis is sufficient if the measurement surface is flat and there is no twisting, no tilting of the surface, and no significant lateral specimen movement occurs during the test.

A 3D DIC system is used for three-dimensional measurements, for example of components and round specimens, and requires special hardware and software. A system for 3D digital image correlation can be connected to the materials testing machine via a module.

Specimen preparation for 2D DIC

A high-contrast pattern can simply and quickly be sprayed onto the specimen.

Additional markings are not necessary for the live strain measurement. Virtual gauge marks are placed on the existing pattern through the software.

Simply see more: the 2D DIC software option for ZwickRoell videoXtens systems

The 2D DIC option does not require additional hardware. The software option is simply combined with the videoXtens and expands the functionality of the already installed strain measurement system

It allows for live strain measurement with a single extensometer, after which the 2D DIC analysis can be carried out.

ZwickRoell array systems offer you high resolution combined with a large field of view. They include several cameras, such as the videoXtens 2-120 HP, which allow you to simply see more in 2D DIC mode.

Fully integrated in testXpert III

The 2D DIC option is fully integrated in testXpert III. This means that with just one software program, you can perform live measurements and 2D DIC analyses. All measured values, test results and images are stored, managed and evaluated together. The strain values obtained from the 2D DIC analysis can be displayed in the stress-strain curve and evaluated. This makes it a powerful option.

In addition, a new specimen can be created via test re-run for different evaluations. This makes the evaluation accessible at any time.

For 2D DIC, a pattern is sprayed onto the specimen, for which solvent-free options are also available. The sprayed-on pattern is also used for axial strain measurement – no additional markings are required.

Example of a 2D DIC analysis process

1. Defining masks and grids

Easily define the image region to be analyzed by means of a mask. Using a toolbox of mask geometries such as circles or polygons, you can also create irregular masks or define recesses. You also have the option of using multiple masks for which different resolutions can be specified.

Three very helpful default settings are available to define the facets and resolution. Settings can also be individually selected or adjusted. In addition, measurements can be carried out on different planes that have varying distances to the test axis, which is the case with offset specimens for example. Here, the distance from the specimen plane to the test axis can be individually adjusted.

2. Starting the correlation

The correlation is used to calculate the displacements and strains between facets using the parameters defined in the mask. Images such as those recorded after specimen fracture can be selectively deselected for the correlation.

3. Analyze

You have a wide selection of analytical tools and displays at your disposal for the analysis process.

The color map and diagram are clearly displayed in a common analysis layout. Analytical tools, such as gauge lengths, can be dragged on the color map to move them, simultaneously displaying current values in the diagram – without time delay! You can use the timeline to access any point in time within the test and apply the analysis tools precisely to the essential regions.

4. Test re-run

Results of the individual 2D DIC analysis tools are combined with the measured values of the live test via the test re-run option in testXpert. Thus, the strain values of the 2D DIC analysis are displayed in the stress-strain curve.

From these combinations, material characteristic values can also be recalculated retrospectively.

2D Digital Image Correlation (DIC)

Various analysis tools for 2D digital image correlation (DIC)

2D Digital Image Correlation (DIC)

Analysis tools can be moved using the mouse, which simultaneously changes the graphical evaluation.

2D Digital Image Correlation (DIC)

Cutting line stack: Selected time steps are displayed in a diagram, making the temporal progression of the cutting line visible.

2D Digital Image Correlation (DIC)

The virtual strain gauges can also be placed on top of each other at different angles.

2D Digital Image Correlation (DIC):Simply Analyze

Analysis tools

Analysis tools in 2D DIC

Measuring points: these can be placed in any desired locations within a strain map.
Gauge lengths or virtual extensometers: establish two points on the strain map, between which the change in distance is to be determined.
Intersections: the strain progression is visualized along the lines. The intersection deforms with the specimen. In addition, there is an intersection stack through which selected time steps are displayed in a diagram, making the time-based development of the intersection visible.
Virtual strain gauges: for the virtual strain gauges, you can individually define the position, size and angle. In addition, multiple virtual strain gauges can be placed on top of each other at different angles. For example, two virtual strain gauges can be combined to form a biaxial strain gauge with measuring grids oriented at 90° to each other. The virtual strain gauges can save you a lot of time and cost.

Creation of graphs / diagrams

Graphical display / diagram

The following measured values can be displayed as strain maps and in diagrams:

Displacements in X direction
Displacements in Y direction
Local longitudinal strains Ɛ_x
Local transverse strains Ɛ_y
Local shear strains Ɛ_xy
Maximum normal strains
Minimum normal strains
Poisson's ratio
Equivalent Von Mises strains

Vector maps can be displayed in all strain maps, showing the main strain directions.

Export options

Export options:

Export of individual data in .csv
Export of the video in .avi
Export color map / diagram in .bmp

What is special about the cutting line in 2D DIC?

With the cutting line, strain progression is displayed along or diagonally across the specimen. The cutting line deforms along with the specimen. It is therefore not a fixed part of the image, but rather a line that actually follows the behavior of the specimen throughout the test.

One special function of the cutting line is the cutting line stack: selected time steps can be displayed in a diagram, allowing you to see the development of the cutting line over time.

What makes virtual strain gauges so efficient?

Virtual strain gauges are efficient because they provide a cost-effective alternative to adhesive strain gauges. This eliminates the time required to apply the strain gauges.

The virtual strain gauges are flexible: position, size and angle are individually determined. They can also be placed on top of each other, whereby two virtual strain gauges create a biaxial strain gauge with measuring grids oriented at 90° to each other.

In addition to local strain information at the strain gauge position, 2D DIC also provides a view of the entire specimen.

What is the benefit of vector maps?

Vector maps display the main strain directions. This makes the strain conditions visible over the entire evaluation range and you quickly gain a good overall understanding of what is going on with the specimen.

In 2D DIC, vector maps display the main strain directions

Related products for determination of 2D Digital Image Correlation (DIC)

Downloads

Product Information:2D Digital Image Correlation (DIC) PDF 1 MB
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