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:''This article is about the deformation of materials. For other meanings, see strain.''
In any branch of science dealing with materials and their behaviour,
'strain' is the geometrical expression of deformation caused by the action of stress on a physical body. Strain is calculated by first assuming a change between two body states: the beginning state and the final state. Then the difference in placement of two points in this body in those two states expresses the numerical value of strain. Strain therefore expresses itself as a change in size and/or shape.
If strain is equal over all parts of a body, it is referred to as ''homogeneous'' strain; otherwise, it is ''inhomogeneous'' strain. In its most general form, the strain is a symmetric tensor.

Contents

Quantifying strain

Linear axial strain at single point

The general case of linear strain

Shear strain

Volumetric strain

The strain tensor

Principal strains in two dimensions

The case of large deformations

Engineering strain vs. true strain

See also

External links

Quantifying strain

Given that strain results in the deformation of a body, it can be measured by calculating the change in length of a line or by the change in angle between two lines (where these lines are theoretical constructs within the deformed body). The change in length of a line is termed the stretch, absolute strain, or extension, and may be written as $delta\; ell$. Then the (relative) strain, $epsilon$, is given by
:
where
: is strain in measured direction
:$ell\_o$ is the original length of the material.
:$ell$ is the current length of the material.
The extension ($delta\; ell$) is positive if the material has gained length (in tension) and negative if it has reduced length (in compression). Because $ell\_o$ is always positive, the sign of the strain is always the same as the sign of the extension.
Strain is a dimensionless quantity. It has no units of measure because in the formula the units of length "cancel out".
Strain is often expressed in dimensions of metres/metre or inches/inch anyway, as a reminder that the number represents a change of length. But the units of length are redundant in such expressions, because they cancel out. When the units of length are left off, strain is seen to be a pure number, which can be expressed as a decimal fraction, a percentage or in parts-per notation. In common solid materials, the change in length is generally a very small fraction of the length, so strain tends to be a very small number. It is very common to express strain in units of micrometre/metre or μm/m. When the units of μm/m are canceled out, strain is expressed as a number followed by μ, the SI prefix all by itself. It is usually clear from the context that μ is used for its SI prefix meaning, which is interchangeable with "x 10⁻⁶" or "ppm" (parts per million), and not one of the many other possible meanings for μ.

Linear axial strain at single point

In the case of measuring strain in the selected point of the body, it is expressed as a strain where the distance $ell$ between two points approaches zero:
:
where
: is strain in measured direction
:$\{\{delta\}\; \{ell\}\; \}$ is the length difference for current length $ell$.
:$ell$ is the current length of the material, which approaches zero.
Therefore 'linear strain' is defined as change of distance in the close proximity of selected point.

The general case of linear strain

For the body of any shape, subjected to any deformation the values of strain will be different depending on the spatial direction of measurement. Considering the linear deformation in the point '''A''' placed at the start of coordinate system and a second point '''B''' placed along the '''x''' axis, which due to deformation has moved to the point '''B' ''' the linear strain will be expressed as:
: over }
Doing similar calculations for axes '''y''' and '''z''' respective values of '''ε_y''' and '''ε_z''' can be obtained. For any given displacement field $overrightarrow\; u$ (the values of displacement vectors for all points in the body) the linear strain can be written as:
:: ; ;
where
: is strain in direction along axis ''i''
:$\{\{partial\; u\_i\}\; over\; \{partial\; i\}\}$ is a differential of $overrightarrow\; u$ at any point in the direction along axis ''i''

Shear strain

Similarly the angular change at any point between two lines crossing this point in a body can be measured as a shear (or shape) strain. Shear strain γ is the limit of ratio of angular difference between any two lines in a body before and after deformation, assuming that the lines lengths are approaching zero. Given a displacement field $overrightarrow\; u$ like above, the shear strain can be written as follows:
:$gamma\_\{xy\}\; =\; \{\{partial\; u\_x\}\; over\; \{partial\; y\}\}\; +\; \{\{partial\; u\_y\}\; over\; \{partial\; x\}\}$ ; $gamma\_\{yz\}\; =\; \{\{partial\; u\_y\}\; over\; \{partial\; z\}\}\; +\; \{\{partial\; u\_z\}\; over\; \{partial\; y\}\}$ ; $gamma\_\{xz\}\; =\; \{\{partial\; u\_x\}\; over\; \{partial\; z\}\}\; +\; \{\{partial\; u\_z\}\; over\; \{partial\; x\}\}$

Volumetric strain

Although linear strain ''ε'' and shear strain ''γ'' completely defines the state of deformation of a body, it is also possible to measure other characteristic strain values, like for example 'volumetric strain', which measures the ratio of change of body's volume. The definition of volumetric strain at selected point is:
:
where
: is volumetric strain
:$V^\{(0)\}$ is initial volume
:$V$ is final volume
For cartesian coordinate system following expression is a first order approximation:
:
where
: is volumetric strain
: are strains along '''x''', '''y''' and '''z''' axis

The strain tensor

Main articles: Strain tensor

Using above notation for linear and shear strain it is possible to express strain as a strain tensor:
:
abla_i u_j +
abla_j u_i}
ight)
using indicial notation or using vector notation:
:
abla}ec{u} + (ec{
abla}ec{u})^T)
Comparing traditional notation with tensor notation following is obtained for cartesian coordinate system:
:
left[{egin{matrix}
{arepsilon _x } & rac {gamma _{xy} } {2} & rac {gamma _{xz} } {2} \
rac {gamma _{yx} } {2} & {arepsilon _y } & rac {gamma _{yz} } {2} \
rac {gamma _{zx} } {2} & rac {gamma _{zy} } {2} & {arepsilon _z }
end{matrix}}
ight]

Then 'volumetric strain' equals:
:
where
'''g^ij''' is a contravariant metric tensor (using tensor notation: )

Principal strains in two dimensions

Because the strain tensor is a real symmetric matrix, by singular value decomposition it can be represented as a set of orthogonal eigenvectors, directions along which there is no shear, only stretching or compression.
Assuming the two dimensional strain tensor given as:
:
left[{egin{matrix}
{arepsilon _x } & {rac {gamma _{xy}} {2}} \
{rac {gamma _{xy}} {2}} & {arepsilon _y } \
end{matrix}}
ight]

Then principal strains are equal to:
:
ight)^2 + left( rac{gamma _{xy}} {2}
ight)^2 }
:
ight)^2 + left( rac{gamma _{xy}} {2}
ight)^2 }

The case of large deformations

Above reasoning assumes that body is subject to ''small deformations''. It must be rememberred that with increasing deformation the linear strain error increases. For ''large deformations'' the 'strain tensor' can be written as:
:
where
'''g_ij''' is the metric tensor of body after deformation
'''g_ij⁽⁰⁾''' is metric tensor of the undeformed body

Engineering strain vs. true strain

In the definition of linear strain (known technically as 'engineering strain'), strains cannot be totaled. Imagine that a body is deformed twice, first by $delta\; ell\_1$ and then by $delta\; ell\_2$ (cumulative deformation). The final strain
:
is slightly different from the sum of the strains:
:
and
:
As long as $delta\; ell\_1\; ll\; ell\_0$, it is possible to write:
:
and thus
:$epsilon\; simeq\; epsilon\_1\; ;\; +\; epsilon\_2\; ;$
'True strain' (aka 'natural strain' and 'logarithmic strain' and 'Hencky's strain'), however, can be totaled. This is defined by:
:
and thus
:
ight )
where
:$ell\_0$ is the original length of the material.
:$ell\_f$ is the final length of the material.
The engineering strain formula is the series expansion of the true strain formula.

See also

★ Stress

★ Strain gauge

★ Strain tensor

★ Stress-strain curve

★ Stretch ratio

★ Hooke's law

★ Poisson's ratio

★ Finite deformation tensors

External links

★ Strain types listed: engineering, true, logarithmic and lagrange