Continuum Exam #2: Lessons 8-10

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What does deformation represent?

A phsyical transofrmation from a reference to a current -may inslcude change in form, motion

What type of function is the mapping funciton?

A proper vector-to-vector function that describes x components wrt X components

TRUE or FALSE The term "velocity" is associated with the referential function. This is what we measure with velocity sensors (e.g. a pitot tube).

TRUE

TRUE or FALSE THe velocity gradient is generally asymmetric and can be decomposed into symmetric and asymmetric parts to highlight physical meaning

TRUE

TRUE or FALSE THe postion of a particle will change from a reference config X to a current config x

TRUE Each particle or point has an associated displacement

TRUE or FALSE We can always visualize affine stretch

TRUE Since an ellipse can always be inserted into a parallelogram -If stretch in an affine defromatino is always int eh from of an ellipse, then it has orthonormal eigenvalues and is a symmetric tensor

TRUE or FALSe Material performance is intrinsically linked to changes in form?

TRUE changes in form (modulus, hardness, toughness, strength, viscosity)

TRUE or FALSE THe mapping function is a one-to-one function and is invertible

TRUE relates X to x can also calculate X if we know x

A ___________ force acts on all mass elements of a body

body

External forces include ___________ and ______________

body and surface

Deformation = ________ + _________

form change + rigid body motion

If matter is viscous, it exhibits time rate dependency and it is necessary to specify the deformation process and follw the

history of deformation

Affine Mappings are called ______________ transformations because little squares will deform just like the big squae

homogeneous

Select any true statement for 3D objects experiencing a non-linear deformation. [2 pts] i. The deformation gradient tensor F will be unique at different material locations. ii. Each infinitesimal volume deforms like an affine transformation. iii. The mapping function is homogenous. iv. The total deformed volume will be a parallelepiped.

i and ii

Select all answers below that are false regarding the identity tensor (can select multiple) i. If U (right stretch tensor) equals the identity tensor, it means no deformation ii. If E (engineering strain) equals the identity tensor, it means no deformation iii. If L (velocity gradient) equals the identity tensor, it means no deformation iv. If F (deformation gradient) equals the identity tensor, it means no deformation

ii and iii

Weak force

involved in radioactive decay

Cauchy stress tensor (\sigma)

linear operator independent of n and replates traction to the cutting plant at a point -when no surface or body torsions exist, \sigma is symmetric

If we want to find how tensors change wrt time for each particle, we calculate the:

material derivative

The descriptions of motion used commonly in contiuum include:

material, referential, spatial

If W is zero at a point, then the point is___________

not rotating -if non zero then the deformation includes rotation -if the vorticity tensor is nonzero and D is zero, then it is a rigid-body rotation (no stretch)

internal forces _________ the tendency for mass to accelerate when an external froce is applied

resist

Deviatoric stress causes changes in ______

shape

Internal forces cause a material to change ________ or __________

shapr of stretch

At an infinitesimal level, any 2D object can be discretized into _________ or _________?

squares; triangles

Polar decomposition

stretch can occur befor or after the roation and therefor we define the right strech tensor U and the left stretch tensor V -R is orthonormal and U is symmetric --> positive definite (strech is never negative)

Rate of deformation tensor is essentially giving the rate that a continuum is being ____

stretched

Lagrangian CV

the CV moves with the material in the spatial configuration

Rate of deformation tensor D is called this because:

the rate fo change of a line element can be deteremined by D -better known as stretch-rate

To determine how tesnors change wrt time at a fixed location, we calculate:

the spatial derivative

Deviatoric stress represents

the stress part of T causing shape change

Dilation stress represents

the stress part of T that is causing volume (area) change

Surface forces or _____________ are contact forces that act on bounding surfaces

tractions

Volume element (Jacobian)

triple scalar product, whcih is qual to the volume defined by the line elements

TRUE or FALSE if F is non symmetric, there must be rotation in the deformtion

true

An area has _________ principal streches and a volume has _________ principal stretchs whcih can be represented by a 2nd order stretch tensor U

two; three

A tensor used to examine the deformation process is the:

velocity gradient

Dialational stress causes changes in ___________

volume

Mapping function equation

x = F dot X + c

What does the continuum assumption mean when applied to mapping function?

-Each point X in the reference config deforms into a distinct point x in the current confih=g -Two different X points cannot deform into the same x -Two different x particles must come from two different X locations

Spatial description

-Fixes attention on a given region of space instead of on a given body of matter -observe changes in physical properties at a fixed region -independent variable is the spatial position, x, at which many particles will pass through over time

Volume element pt II

-Jacobian or jacobian determinant (scalar=determinant of F)

Octahedral Plane

-To calculate a scalar measure, we need to determine the normal and shear stress components on the Octahedral plane

Dilational stress (spherical stress)

-a hydrostatic state of stress (equal stress on all surfaces) -first find the mean normal stress (negative of pressure) and multiple it by I

Referential description

-independent variable is the position vector, X, pointing to a particle in an arbitrary reference configuration -when the reference configure is at t=0, it is often called the lagrangian description

Affine transformations have the following properties

-squares become parallelograms -cubes become parallelopipeds -line segments become line segments of differnt orientation and length but remain straight -parallel lines remain parallel lines -circles become ellipses -speheres become ellipses

Since \sigma is symmetric, any general rules for 2nd order symmetric tensors must apply What are these rules?

1. 3 principal stresses: \sigma_1 ,\sigma_2, \sigma_3 (invariant triplet) 2. three characteristic invariants: I_1, I_2, I3 (invariant triplet) 3. 3 principal directions: p_1, p_2, p_3 4. no skew part 5. normal and shear components of \sigma can be viewed using mohr's circle

What are the forces most relevant to continuum?

1. Electromagetic 2. Graviational

Steps to calculate U,V,R

1. calculate [F] 2. calculate [C_lab] 3. eigen and [Q] 4. C in prinipal basis 5. U in principle 6. U in lab 7. R in lab 8. V in lab

List one inherent disadvantage and two inherent advantages to using S.

Advantage: S is a symmetric tensor (unlike P, similar to T) and therefore has properties similar to all symmetric tensors (e.g. orthonormal eigenvectors, scalar invariants). Advantage: S does not have moving boundaries (similar to P, unlike T). This can simplify calculations of moving objects. Disadvantage: S is difficult to interpret. When we "pull-back" PK1 stress, the result is not physically meaningful. It is simply a mathematical mechanism to create a symmetric tensor that has both unit basis, or "legs", in the reference configuration. Remember: If you know F, you can easily go back and forth between the different stress tensors. Therefore, you can perform a calculation using S, and then "push-it-forward" into T, a more physically meaningful stress tensor.

At what stretch are the strain measures close to equal? Which strain measure(s) is most physically meaningful for very large compressions and why?

All strain measures are equal when stretch equals 1 (strain = 0 at this point). Under large compression, true and euler strain have more physical meaning, since their strains approach negative infinity, and are more sensitive to large compressions.

In Matlab, graph the Seth hill family of strains for a 1D problems with λ going from 0.1 to 4 (y-axis is strain, x-axis is λ). Label the curves (can be by hand). At what stretch are the strain measures close to equal? Which strain measure(s) is most physically meaningful for very large compressions and why?

All strain measures are equal when stretch equals 1 (strain = 0 at this point). Under large compression, true and euler strain have more physical meaning, since their strains approach negative infinity, and are more sensitive to large compressions.

HW7_2: Illustrate the reasons that the deformations described by 1a, 1b, 1c and 1d are either affine or non-affine.

All the above deformations are affine. As an example, you can see that 1c is "homogenous" as all the little squares (light blue) deform just like the big square (dark blue).

Eulerian CV

Fixed in the spatial configuration

TRUE or FALSE The tangenetial component of traction on the octahedral plane is the "Octagedral Shear Stress" \sigma_oct

TRUE

A "simple shear" experiment is often used to characterize the mechanical properties of materials and is shown below. The deformation from this experiment is similar to problem 1d. What do you think would happen with R, U and V if the material were infinitely pulled along the direction of the black arrow?

As the material is pulled, the rotation would increase to 90 degrees (CW). U would eventually have only large stretches in the e2 direction (vertical stretch, then rotate), while V would only have large positive stretches in the e1 direction (rotate and then horizontal stretch).

Strong force

Binds protons and neutrons

Is cauchy stress in the reference or current configuraton?

Current configureation

Calculate GL strain E using F

E=0.5(F^TF-I)

The spatial description is most often used in fluid mechanics and is offed called the ________--

Eulerian description

Newtons third law

Every force has an equal and opposite force. Thus, all forces are interactions between two bodies

TRUE or FALSE Since affine stretch is linear, a square will always maintain contact with the mid points of the parallelogram edges

FALSE An ellipse will

TRUE or FALSE For a non-linear transformations, each little square has the same F tensor

FALSE each little square has its own unique F tensor

How to calculate non-linear transformations?

For non-linear transformations, each little square deforms differently from other squares; however, within the limit of infinitesimal squares they all deform like an affine transformation locally Difference: each little square has its own unique F tensor

Newtons second law

Force equals a change in linear momentum, p F=dp/dt=ma

________ forces resist the tendency for one part of an object toa ccelerate away form another part

Internal froces

If stretch in an affine defromatino is always in the from of an ellipse, what does this mean?

It has orthonormal eigenvalues and is a symmetric tensor

Why is octahedral shear stress useful?

It is a scalar measure of the amount of stress being applied towards changing the "shape" of a material

What is the minimum number of line elements needed to measure in order to use the equation in (2a) to calculate in-plane components of E. Show mathematically

It takes 3 line elements

How do we determine the time rate of a tensor field within a CV

Leibniz's Rule

Is the term "velocity" associated with spatial description?

NO! This measure of change in position with time has less physical meaning, and the term "velocity" is not associated with the spatial description.

First Piola-Kirchhoff stress (PK1)

New tensor P p=N*P **PK1 stress (note that P is non-symmetric)

In the problem below, the ellipse has the same shape for both deformations. Is the deformation the same? Illustrate graphically and mathematically why or why not.

No, the deformation is not the same. The stretch is approximately the same, but the rotation is different. In the first figure, the square is stretched "off-axis" of the e1 and e2 surface, and then a "smaller" rotation is applied. In the second figure, the square is stretched along the e1 and e2 reference axis, and a "larger" rotation is applied. The differences in F can be seen below (can use matlab program to calculate R and U).

Can we simply analyze form change from the deformation tensor?

Not quite. The deformation gradient is a function of roation and rotation does not cause a change in form

3D infinitesimal strain

ONly approximated for very small deformations iwth no rotations. -If rotations exist, then infinitesimal strain is prone to error since the strain value is dependent on rotation

_________ stress is equivalent to von Mises stress or effective stress

Octahedral

Explain the relationship between pressure and the stress tensor

Pressure is a scalar and is equal to the negative mean normal stress (σmean): p=-s_mean The stress tensor is a 2nd order tensor. Pressure represents the normal component values along the diagonal of the stress tensor.

V

Rotated first then stretched

The vorticity tensor, W, is a useful indicator of what?

Rotation

Second Piola-Kirchhoff

S is symmetrical -has little physical meaning, however, it can be useful for "packaging" your stress and then converting back into a more physically meaningful stress at a later time point

One dimensional strain

Seth hill family of strain for 1D

Three dimensional strain

Seth hill. Need to consider which stretch, the right stretch U or left stretch V

Write one important similarity and one important difference between octahedral shear stress and the deviatoric part of the stress tensor:

Similarity: Both are a quantitative measures of stress that go into changing a materials shape (i.e. distorting a material) [1.5 pts] Difference: Octahedral shear stress is a scalar, while the deviatoric part of the stress tensor is a 2nd order tensor. [1.5 pts]

Would you classify D as a true time rate? Why or why not?

Since this tensor is symmetric, it has orthogonal principal axes. Therefore, D is similar to U and V, but instead of representing stretch like U and V, D represents a form of stretch rate. However, a "time rate" is a change in a function w.r.t. time, and in this case, it is a change in velocity w.r.t. position, so NO it is not a true time rate.

U

Stretched first then rotated

Deviatoric stress is calculated by:

Subtracting mean stress from T

TRUE or FALSE Strain is a symmetric 2nd order tensor

TRUE

TRUE or FALSE Stretch of a 2nd order tensor is very similar to strech of a line

TRUE

TRUE or FALSE The normal component of traction on the octahedral plane is the "mean stress" \sigma_m

TRUE

Optical Coherence Tomography (OCT) can be used to capture volumetric images of the eye retina, and the coordinates of pixel speckles can be automatically tracked using specialized software before and after a deformation. How could the method from (2d) be used to determine the volumetric strain of a patient's retina after surgery using OCT images. How many line elements would be needed to measure strain at a point in 3D?

The coordinates of pixel speckles can be divided into groups of four non-linear neighboring pixels. A system of equations can then be used to efficiently calculate the volumetric Green-Lagrange strain in each tetrahedral region from a reference to current configuration. The four points will give 6 lines, which are necessary to calculate the 6 unknowns of E.

What is F in the mapping function?

The defromation gradient tensor -components represent the change in x relative to X

What do lamda_1 and lamda_2 represent?

The eigenvalues of U

What is strain?

The normalized measure of deformation whithout rigid body motion

Explain the physical meaning of the octahedral shear stress, and explain why this value is useful when interpreting the stresses in an object.

The octahedral shear stress (also known as effective stress and von Mises stress) is a scalar measure that describes the amount of stress going into shape change (i.e. object distortion). This is useful, since scalar values can be used as thresholds to predict when yielding or failure begins. For example, if I want to predict when an object yields, I could run experiments to determine the octahedral shear stress at failure and then design parts not to exceed the octahedral shear stress. The deviatoric stress tensor also describes shape change, but it is a 2nd order tensor with nine components, so you wouldn't be able to use deviatoric stress as a scalar threshold for failure.

What does X represent in the material description?

The particle and is not a position vector that points to the particle

Showing all steps, calculate the 1st Piola Kirchoff stress tensor, P, at time 1 and time 2 (w.r.t. time = 0). Give a physical interpretation of P relative to the deformed object

The same force is being applied in the current and reference configuration, however, the surface area in the current configuration is ½ the surface area in the reference configuration. This means that if the traction on the current vertical surface area were applied to the reference surface area, the traction would be reduced by ½. This is reflected in the P tensor.

What is the mapping function analogous to?

The slope intercept equation -translation c is analogous to the y-intercept

Interpret the physical meaning of the vorticity vector in relation to the kitty's motion.

This point on the Kitty's body at time t=1s is rotating about the x2 axis in the counterclockwise direction.

If E in the above equation is the Green-Lagrange strain for a fixed region (spatial) on a deformed elastomer, what would this equation physically determine?

This would be the material derivative, so the physical meaning is the change in strain w.r.t. time for a particle.

Gravitational force

Two bodies attract

What is the maximum and minimum "stretching" calculated from the symmetric part of the velocity gradient in (b)? What is the physical interpretation of these results w.r.t. the cat?

Using the eig function in matlab. Max stretch rate is 2, min stretch rate is -1. Over time the cat is elongating along the e3 principal axis, and contracting along the e1 principal axis. Note: the e1 and e3 principal axes are not aligned with the lab basis.

Octaheadral plane from principal stresses

We know n of the ocathedral plane wrt the principal basis

Material Description

We observe changes in position and physical properties as the material body X (particle) moves in space and time -independent variable is the particle

Newtons first law

Without an applied force, objects remain at rest or constant velocity (law of inertia)

Will deforming an obeject in tension create surfaces thate experience shear?

Yes any surafce not aligned with the eigenvector will have tangential component

Draw the deformations described by the U and V you calculated in problem 4c. Draw an ellipse to calculate λ1, λ1, and R for both U and V. Explain whether your answers make sense.

Yes, it makes sense. The eigenvalues for both U and V are the same, and both have no rotation (remember, U and V represent stretch and should have no rotation component). The orientation of the eigenvalues (i.e. eigenvectors) are different between U and V, and this difference is the rotation of the deformation, which is 22 degrees in the e1 - e2 plane.

2nd Piola Kirchoff stress tensor, S

You can visualize the stress tensor S as "pulling-back" the current traction vector, t, from P into the ref configuration. This is no different than pulling back a differential line element from the current to the reference configuration (dx=FdX), except in this case the line elements are column vectors of P. For this problem, this "pull-back" scaled the current traction on the vertical surface by ¼.

Showing all steps, calculate the 2nd Piola Kirchoff stress tensor, S, at time 1 and time 2 (w.r.t. time=0). Give a physical interpretation of S relative to the deformed object.

You can visualize the stress tensor S as "pulling-back" the current traction vector, t, from P into the ref configuration. This is no different than pulling back a differential line element from the current to the reference configuration (dx=FdX), except in this case the line elements are column vectors of P. For this problem, this "pull-back" scaled the current traction on the vertical surface by ¼.

Cramers rule

a method that uses determinants to solve a system of linear equations [x]=[A^-1][b]

When we use, X, we are identifying what?

a single particle

When we use, x, we are identifying what?

a single region that many particles will pass

When we describe a time-dependent tensor using the reference coordinate system (X1,X2,X3) we are describing....

a tensor field for a fixed particle -Referential description

When we describe a time-dependent tensor using the reference coordinate system (x1,x2,x3) we are describing....

a tensor field for a fixed position

The deformation is not just a function of space but __________-

also a function of time

Electromagnetic force

charged particles attract and repulse

At an infintesimal level, any 3D object can discretized into _______ or _______

cubes or tetrahedrals (only 4 points needed to define a volume)

When external forces are applied to objects the forces cause _______________

deformation

For a line element, what for of x and X do you use?

dx and dX

Since forces are directional, tehy are vectors, and can be classified as _________- or - _____________

external ; internal


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