Ultralimit

From formulasearchengine
Revision as of 18:57, 1 December 2013 by 37.191.198.252 (talk) (Limit of a sequence of points with respect to an ultrafilter: Removed redunant "Hausdorff" criterion for a metric space.)
Jump to navigation Jump to search

The derivatives of scalars, vectors, and second-order tensors with respect to second-order tensors are of considerable use in continuum mechanics. These derivatives are used in the theories of nonlinear elasticity and plasticity, particularly in the design of algorithms for numerical simulations.[1]

The directional derivative provides a systematic way of finding these derivatives.[2]

Derivatives with respect to vectors and second-order tensors

The definitions of directional derivatives for various situations are given below. It is assumed that the functions are sufficiently smooth that derivatives can be taken.

Derivatives of scalar valued functions of vectors

Let f(v) be a real valued function of the vector v. Then the derivative of f(v) with respect to v (or at v) in the direction u is the vector defined as

f𝐯𝐮=Df(𝐯)[𝐮]=[ddαf(𝐯+α𝐮)]α=0

for all vectors u.

Properties:

1) If f(𝐯)=f1(𝐯)+f2(𝐯) then f𝐯𝐮=(f1𝐯+f2𝐯)𝐮

2) If f(𝐯)=f1(𝐯)f2(𝐯) then f𝐯𝐮=(f1𝐯𝐮)f2(𝐯)+f1(𝐯)(f2𝐯𝐮)

3) If f(𝐯)=f1(f2(𝐯)) then f𝐯𝐮=f1f2f2𝐯𝐮

Derivatives of vector valued functions of vectors

Let f(v) be a vector valued function of the vector v. Then the derivative of f(v) with respect to v (or at v) in the direction u is the second order tensor defined as

𝐟𝐯𝐮=D𝐟(𝐯)[𝐮]=[ddα𝐟(𝐯+α𝐮)]α=0

for all vectors u.

Properties:
1) If 𝐟(𝐯)=𝐟1(𝐯)+𝐟2(𝐯) then 𝐟𝐯𝐮=(𝐟1𝐯+𝐟2𝐯)𝐮
2) If 𝐟(𝐯)=𝐟1(𝐯)×𝐟2(𝐯) then 𝐟𝐯𝐮=(𝐟1𝐯𝐮)×𝐟2(𝐯)+𝐟1(𝐯)×(𝐟2𝐯𝐮)
3) If 𝐟(𝐯)=𝐟1(𝐟2(𝐯)) then 𝐟𝐯𝐮=𝐟1𝐟2(𝐟2𝐯𝐮)

Derivatives of scalar valued functions of second-order tensors

Let f(𝑺) be a real valued function of the second order tensor 𝑺. Then the derivative of f(𝑺) with respect to 𝑺 (or at 𝑺) in the direction 𝑻 is the second order tensor defined as

f𝑺:𝑻=Df(𝑺)[𝑻]=[ddαf(𝑺+α𝑻)]α=0

for all second order tensors 𝑻.

Properties:
1) If f(𝑺)=f1(𝑺)+f2(𝑺) then f𝑺:𝑻=(f1𝑺+f2𝑺):𝑻
2) If f(𝑺)=f1(𝑺)f2(𝑺) then f𝑺:𝑻=(f1𝑺:𝑻)f2(𝑺)+f1(𝑺)(f2𝑺:𝑻)
3) If f(𝑺)=f1(f2(𝑺)) then f𝑺:𝑻=f1f2(f2𝑺:𝑻)

Derivatives of tensor valued functions of second-order tensors

Let 𝑭(𝑺) be a second order tensor valued function of the second order tensor 𝑺. Then the derivative of 𝑭(𝑺) with respect to 𝑺 (or at 𝑺) in the direction 𝑻 is the fourth order tensor defined as

𝑭𝑺:𝑻=D𝑭(𝑺)[𝑻]=[ddα𝑭(𝑺+α𝑻)]α=0

for all second order tensors 𝑻.

Properties:
1) If 𝑭(𝑺)=𝑭1(𝑺)+𝑭2(𝑺) then 𝑭𝑺:𝑻=(𝑭1𝑺+𝑭2𝑺):𝑻
2) If 𝑭(𝑺)=𝑭1(𝑺)𝑭2(𝑺) then 𝑭𝑺:𝑻=(𝑭1𝑺:𝑻)𝑭2(𝑺)+𝑭1(𝑺)(𝑭2𝑺:𝑻)
3) If 𝑭(𝑺)=𝑭1(𝑭2(𝑺)) then 𝑭𝑺:𝑻=𝑭1𝑭2:(𝑭2𝑺:𝑻)
4) If f(𝑺)=f1(𝑭2(𝑺)) then f𝑺:𝑻=f1𝑭2:(𝑭2𝑺:𝑻)

Gradient of a tensor field

The gradient, 𝑻, of a tensor field 𝑻(𝐱) in the direction of an arbitrary constant vector c is defined as:

𝑻𝐜=ddα𝑻(𝐱+α𝐜)|α=0

The gradient of a tensor field of order n is a tensor field of order n+1.

Cartesian coordinates

Template:Einstein summation convention

If 𝐞1,𝐞2,𝐞3 are the basis vectors in a Cartesian coordinate system, with coordinates of points denoted by (x1,x2,x3), then the gradient of the tensor field 𝑻 is given by

𝑻=𝑻xi𝐞i

Since the basis vectors do not vary in a Cartesian coordinate system we have the following relations for the gradients of a scalar field ϕ, a vector field v, and a second-order tensor field 𝑺.

ϕ=ϕxi𝐞i𝐯=(vj𝐞j)xi𝐞i=vjxi𝐞j𝐞i𝑺=(Sjk𝐞j𝐞k)xi𝐞i=Sjkxi𝐞j𝐞k𝐞i

Curvilinear coordinates

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. Template:Einstein summation convention

If 𝐠1,𝐠2,𝐠3 are the contravariant basis vectors in a curvilinear coordinate system, with coordinates of points denoted by (ξ1,ξ2,ξ3), then the gradient of the tensor field 𝑻 is given by (see [3] for a proof.)

𝑻=𝑻ξi𝐠i

From this definition we have the following relations for the gradients of a scalar field ϕ, a vector field v, and a second-order tensor field 𝑺.

ϕ=ϕξi𝐠i𝐯=(vj𝐠j)ξi𝐠i=(vjξi+vkΓikj)𝐠j𝐠i=(vjξivkΓijk)𝐠j𝐠i𝑺=(Sjk𝐠j𝐠k)ξi𝐠i=(SjkξiSlkΓijlSjlΓikl)𝐠j𝐠k𝐠i

where the Christoffel symbol Γijk is defined using

Γijk𝐠k=𝐠iξjΓijk=𝐠iξj𝐠k=𝐠i𝐠kξj

Cylindrical polar coordinates

In cylindrical coordinates, the gradient is given by

ϕ=ϕr𝐞r+1rϕθ𝐞θ+ϕz𝐞z𝐯=vrr𝐞r𝐞r+1r(vrθvθ)𝐞r𝐞θ+vrz𝐞r𝐞z+vθr𝐞θ𝐞r+1r(vθθ+vr)𝐞θ𝐞θ+vθz𝐞θ𝐞z+vzr𝐞z𝐞r+1rvzθ𝐞z𝐞θ+vzz𝐞z𝐞z𝑺=Srrr𝐞r𝐞r𝐞r+1r[Srrθ(Sθr+Srθ)]𝐞r𝐞r𝐞θ+Srrz𝐞r𝐞r𝐞z+Srθr𝐞r𝐞θ𝐞r+1r[Srθθ+(SrrSθθ)]𝐞r𝐞θ𝐞θ+Srθz𝐞r𝐞θ𝐞z+Srzr𝐞r𝐞z𝐞r+1r[SrzθSθz]𝐞r𝐞z𝐞θ+Srzz𝐞r𝐞z𝐞z+Sθrr𝐞θ𝐞r𝐞r+1r[Sθrθ+(SrrSθθ)]𝐞θ𝐞r𝐞θ+Sθrz𝐞θ𝐞r𝐞z+Sθθr𝐞θ𝐞θ𝐞r+1r[Sθθθ+(Srθ+Sθr)]𝐞θ𝐞θ𝐞θ+Sθθz𝐞θ𝐞θ𝐞z+Sθzr𝐞θ𝐞z𝐞r+1r[Sθzθ+Srz]𝐞θ𝐞z𝐞θ+Sθzz𝐞θ𝐞z𝐞z+Szrr𝐞z𝐞r𝐞r+1r[SzrθSzθ]𝐞z𝐞r𝐞θ+Szrz𝐞z𝐞r𝐞z+Szθr𝐞z𝐞θ𝐞r+1r[Szθθ+Szr]𝐞z𝐞θ𝐞θ+Szθz𝐞z𝐞θ𝐞z+Szzr𝐞z𝐞z𝐞r+1rSzzθ𝐞z𝐞z𝐞θ+Szzz𝐞z𝐞z𝐞z

Divergence of a tensor field

The divergence of a tensor field 𝑻(𝐱) is defined using the recursive relation

(𝑻)𝐜=(𝐜𝑻);𝐯=tr(𝐯)

where c is an arbitrary constant vector and v is a vector field. If 𝑻 is a tensor field of order n > 1 then the divergence of the field is a tensor of order n−1.

Cartesian coordinates

Template:Einstein summation convention In a Cartesian coordinate system we have the following relations for a vector field v and a second-order tensor field 𝑺.

𝐯=vixi𝑺=Skixi𝐞k

Note that in the case of the second-order tensor field, we have[4]

𝑺div𝑺=𝑺T.

Curvilinear coordinates

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. Template:Einstein summation convention In curvilinear coordinates, the divergences of a vector field v and a second-order tensor field 𝑺 are

𝐯=(viξi+vkΓiki)𝑺=(SikξiSlkΓiilSilΓikl)𝐠k

Cylindrical polar coordinates

In cylindrical polar coordinates

𝐯=vrr+1r(vθθ+vr)+vzz𝑺=Srrr𝐞r+Srθr𝐞θ+Srzr𝐞z+1r[Sθrθ+(SrrSθθ)]𝐞r+1r[Sθθθ+(Srθ+Sθr)]𝐞θ+1r[Sθzθ+Srz]𝐞z+Szrz𝐞r+Szθz𝐞θ+Szzz𝐞z

Curl of a tensor field

The curl of an order-n > 1 tensor field 𝑻(𝐱) is also defined using the recursive relation

(×𝑻)𝐜=×(𝐜𝑻);(×𝐯)𝐜=(𝐯×𝐜)

where c is an arbitrary constant vector and v is a vector field.

Curl of a first-order tensor (vector) field

Consider a vector field v and an arbitrary constant vector c. In index notation, the cross product is given by

𝐯×𝐜=eijkvjck𝐞i

where eijk is the permutation symbol. Then,

(𝐯×𝐜)=eijkvj,ick=(eijkvj,i𝐞k)𝐜=(×𝐯)𝐜

Therefore

×𝐯=eijkvj,i𝐞k

Curl of a second-order tensor field

For a second-order tensor 𝑺

𝐜𝑺=cmSmj𝐞j

Hence, using the definition of the curl of a first-order tensor field,

×(𝐜𝑺)=eijkcmSmj,i𝐞k=(eijkSmj,i𝐞k𝐞m)𝐜=(×𝑺)𝐜

Therefore, we have

×𝑺=eijkSmj,i𝐞k𝐞m

Identities involving the curl of a tensor field

The most commonly used identity involving the curl of a tensor field, 𝑻, is

×(𝑻)=0

This identity hold for tensor fields of all orders. For the important case of a second-order tensor, 𝑺, this identity implies that

×𝑺=0Smi,jSmj,i=0

Derivative of the determinant of a second-order tensor

The derivative of the determinant of a second order tensor 𝑨 is given by

𝑨det(𝑨)=det(𝑨)[𝑨1]T.

In an orthonormal basis, the components of 𝑨 can be written as a matrix A. In that case, the right hand side corresponds the cofactors of the matrix.

Derivatives of the invariants of a second-order tensor

The principal invariants of a second order tensor are

I1(𝑨)=tr𝑨I2(𝑨)=12[(tr𝑨)2tr𝑨2]I3(𝑨)=det(𝑨)

The derivatives of these three invariants with respect to 𝑨 are

I1𝑨=1I2𝑨=I11𝑨TI3𝑨=det(𝑨)[𝑨1]T=I21𝑨T(I11𝑨T)=(𝑨2I1𝑨+I21)T

Derivative of the second-order identity tensor

Let 1 be the second order identity tensor. Then the derivative of this tensor with respect to a second order tensor 𝑨 is given by

1𝑨:𝑻=𝟢:𝑻=0

This is because 1 is independent of 𝑨.

Derivative of a second-order tensor with respect to itself

Let 𝑨 be a second order tensor. Then

𝑨𝑨:𝑻=[α(𝑨+α𝑻)]α=0=𝑻=𝖨:𝑻

Therefore,

𝑨𝑨=𝖨

Here 𝖨 is the fourth order identity tensor. In index notation with respect to an orthonormal basis

𝖨=δikδjl𝐞i𝐞j𝐞k𝐞l

This result implies that

𝑨T𝑨:𝑻=𝖨T:𝑻=𝑻T

where

𝖨T=δjkδil𝐞i𝐞j𝐞k𝐞l

Therefore, if the tensor 𝑨 is symmetric, then the derivative is also symmetric and we get

𝑨𝑨=𝖨(s)=12(𝖨+𝖨T)

where the symmetric fourth order identity tensor is

𝖨(s)=12(δikδjl+δilδjk)𝐞i𝐞j𝐞k𝐞l

Derivative of the inverse of a second-order tensor

Let 𝑨 and 𝑻 be two second order tensors, then

𝑨(𝑨1):𝑻=𝑨1𝑻𝑨1

In index notation with respect to an orthonormal basis

Aij1AklTkl=Aik1TklAlj1Aij1Akl=Aik1Alj1

We also have

𝑨(𝑨T):𝑻=𝑨T𝑻T𝑨T

In index notation

Aji1AklTkl=Ajk1TlkAli1Aji1Akl=Ali1Ajk1

If the tensor 𝑨 is symmetric then

Aij1Akl=12(Aik1Ajl1+Ail1Ajk1)

Integration by parts

Domain Ω, its boundary Γ and the outward unit normal 𝐧

Another important operation related to tensor derivatives in continuum mechanics is integration by parts. The formula for integration by parts can be written as

Ω𝑭𝑮dΩ=Γ𝐧(𝑭𝑮)dΓΩ𝑮𝑭dΩ

where 𝑭 and 𝑮 are differentiable tensor fields of arbitrary order, 𝐧 is the unit outward normal to the domain over which the tensor fields are defined, represents a generalized tensor product operator, and is a generalized gradient operator. When 𝑭 is equal to the identity tensor, we get the divergence theorem

Ω𝑮dΩ=Γ𝐧𝑮dΓ.

We can express the formula for integration by parts in Cartesian index notation as

ΩFijk....Glmn...,pdΩ=ΓnpFijk...Glmn...dΓΩGlmn...Fijk...,pdΩ.

For the special case where the tensor product operation is a contraction of one index and the gradient operation is a divergence, and both 𝑭 and 𝑮 are second order tensors, we have

Ω𝑭(𝑮)dΩ=Γ𝐧(𝑮𝑭T)dΓΩ(𝑭):𝑮TdΩ.

In index notation,

ΩFijGpj,pdΩ=ΓnpFijGpjdΓΩGpjFij,pdΩ.

References

  1. J. C. Simo and T. J. R. Hughes, 1998, Computational Inelasticity, Springer
  2. J. E. Marsden and T. J. R. Hughes, 2000, Mathematical Foundations of Elasticity, Dover.
  3. Ogden, R. W., 2000, Nonlinear Elastic Deformations, Dover.
  4. http://homepages.engineering.auckland.ac.nz/~pkel015/SolidMechanicsBooks/Part_III/Chapter_1_Vectors_Tensors/Vectors_Tensors_14_Tensor_Calculus.pdf

See also