VoigtOperations.h
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Created: Sat, Sep 7, 02:47

VoigtOperations.h
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	#ifndef VOIGT_OPERATIONS_H
	#define VOIGT_OPERATIONS_H
	#include "MatrixDef.h"
	#include "MatrixLibrary.h"



	// Voigt indexing puts a symmetric 3x3 matrix into a
	// vector form: [0 1 2 3 4 5]
	//
	// matrix form: [[ 0 5 4 ]
	// [ 5 1 3 ]
	// [ 4 3 2 ]]
	//
	// unsymmetric version
	// vector form: [0 1 2 3 4 5 6 7 8]
	//
	// matrix form: [[ 0 5 4 ]
	// [ 8 1 3 ]
	// [ 7 6 2 ]]

	namespace voigt3 {


	//const int voigt_idx1_symm[] = {0,1,2,1,0,0}; // first packed voigt index
	//const int voigt_idx2_symm[] = {0,1,2,2,2,1}; // second packed voigt index
	const int voigt_idx1[] = {0,1,2,1,0,0,2,2,1}; // first packed voigt index
	const int voigt_idx2[] = {0,1,2,2,2,1,1,0,0}; // second packed voigt index
	// const int voigt_idx1[] = {0,1,2,0,0,1,1,2,2}; // first packed voigt index
	// const int voigt_idx2[] = {0,1,2,1,2,2,0,0,1}; // second packed voigt index


	//* Computes a symmetric matrix-matrix product
	//* Inputs 6-length vectors A, B
	inline DENS_VEC dsymm(const DENS_VEC &A, const DENS_VEC &B)
	{
	DENS_VEC C(6,false);
	C(0) = A(0)B(0)+A(5)B(5)+A(4)*B(4);
	C(1) = A(5)B(5)+A(1)B(1)+A(3)*B(3);
	C(2) = A(4)B(4)+A(3)B(3)+A(2)*B(2);
	C(3) = A(5)B(4)+A(1)B(3)+A(3)*B(2);
	C(4) = A(0)B(4)+A(5)B(3)+A(4)*B(2);
	C(5) = A(0)B(5)+A(5)B(1)+A(4)*B(3);
	return C;
	}

	//* Returns the trace of a 3x3 matrix in symmetric voigt form.
	inline double tr(const DENS_VEC &A)
	{
	return A(0) + A(1) + A(2);
	}

	//* Computes the determinant of a 3x3 matrix in symmetric voigt form.
	inline double det(const DENS_VEC &A)
	{
	return A(0) * (A(1)A(2)-A(3)A(3))
	-A(5) * (A(5)A(2)-A(3)A(4))
	+A(4) * (A(5)A(3)-A(1)A(4));
	}

	//* Returns the derivative of C*C in voigt notation.
	inline DENS_MAT derivative_of_square(const DENS_VEC &C)
	{
	DENS_MAT D(6,6);
	D(0,0)=2.0*C(0); D(0,1)=0.0; D(0,2)=0.0;
	D(1,0)=0.0; D(1,1)=2.0*C(1); D(1,2)=0.0;
	D(2,0)=0.0; D(2,1)=0.0; D(2,2)=2.0*C(2);

	D(0,3)=0.0; D(0,4)=2.0C(4); D(0,5)=2.0C(5);
	D(1,3)=2.0C(3); D(1,4)=0.0; D(1,5)=2.0C(5);
	D(2,3)=2.0C(3); D(2,4)=2.0C(4); D(2,5)=0.0;

	D(3,0)=0.0; D(3,1)=C(3); D(3,2)=C(3);
	D(4,0)=C(4); D(4,1)=0.0; D(4,2)=C(4);
	D(5,0)=C(5); D(5,1)=C(5); D(5,2)=0.0;

	D(3,3)=C(1)+C(2); D(3,4)=C(5); D(3,5)=C(4);
	D(4,3)=C(5); D(4,4)=C(0)+C(2); D(4,5)=C(3);
	D(5,3)=C(4); D(5,4)=C(3); D(5,5)=C(0)+C(1);
	return D;
	}

	//* Computes the inverse of a 3x3 matrix in symmetric voigt form.
	inline DENS_VEC inv(const DENS_VEC &A)
	{
	DENS_VEC B(6,false);
	const double inv_det = 1.0/det(A);
	B(0) = (A(1)A(2)-A(3)A(3))*inv_det;
	B(1) = (A(0)A(2)-A(4)A(4))*inv_det;
	B(2) = (A(0)A(1)-A(5)A(5))*inv_det;
	B(3) = (A(4)A(5)-A(0)A(3))*inv_det;
	B(4) = (A(5)A(3)-A(4)A(1))*inv_det;
	B(5) = (A(4)A(3)-A(5)A(2))*inv_det;
	return B;
	}

	//* Returns the identify matrix in voigt form, optionally scaled by a factor.
	inline DENS_VEC eye(INDEX N=3, double scale=1.0)
	{
	const double dij[] = {0.0, scale};
	const INDEX voigt_size = NN-((NN-N)>>1); // total - symmetric elements
	DENS_VEC I(voigt_size,false);
	for (INDEX i=0; i<voigt_size; i++) I(i) = dij[i<N];
	return I;
	}


	//* Returns the voigt form of a symmetric matrix.
	// consistent with voigt_idx1,2
	inline DENS_VEC to_voigt(const DENS_MAT &C)
	{
	DENS_VEC B(6,false);
	B(0)=C(0,0);
	B(1)=C(1,1);
	B(2)=C(2,2);
	B(3)=C(1,2); // take upper triangle entries
	B(4)=C(0,2);
	B(5)=C(0,1);
	return B;
	}

	//* Returns a symmetric matrix form a voigt form.
	// consistent with voigt_idx1,2
	inline DENS_MAT from_voigt(const DENS_VEC &B)
	{
	DENS_MAT C(3,3,false);
	C(0,0)=B(0); C(0,1)=B(5); C(0,2)=B(4);
	C(1,0)=B(5); C(1,1)=B(1); C(1,2)=B(3);
	C(2,0)=B(4); C(2,1)=B(3); C(2,2)=B(2);
	return C;
	}

	//* Returns the voigt form of an unsymmetric matrix.
	// consistent with voigt_idx1,2
	inline DENS_VEC to_voigt_unsymmetric(const DENS_MAT &C)
	{
	DENS_VEC B(9,false);
	B(0)=C(0,0);
	B(1)=C(1,1);
	B(2)=C(2,2);
	B(3)=C(1,2); // upper triangle entries
	B(4)=C(0,2);
	B(5)=C(0,1);
	B(6)=C(2,1); // lower triangle entries
	B(7)=C(2,0);
	B(8)=C(1,0);
	return B;
	}

	//* Returns a symmetric matrix form a voigt form.
	// consistent with voigt_idx1,2
	inline DENS_MAT from_voigt_unsymmetric(const DENS_VEC &B)
	{
	DENS_MAT C(3,3,false);
	C(0,0)=B(0); C(0,1)=B(5); C(0,2)=B(4);
	C(1,0)=B(8); C(1,1)=B(1); C(1,2)=B(3);
	C(2,0)=B(7); C(2,1)=B(6); C(2,2)=B(2);
	return C;
	}

	//* adds the identity to an unsymmetric matrix form
	inline void add_identity_voigt_unsymmetric(DENS_VEC &B)
	{
	B(0) +=1;
	B(1) +=1;
	B(2) +=1;
	}

	//* Converts voigt vector form to 3x3 matrix for non-symmetric tensor at specified node.
	inline void vector_to_matrix(const int i, const DENS_MAT & IN, DENS_MAT & OUT)
	{
	OUT.reset(3,3);
	OUT(0,0)=IN(i,0); OUT(0,1)=IN(i,1); OUT(0,2)=IN(i,2);
	OUT(1,0)=IN(i,3); OUT(1,1)=IN(i,4); OUT(1,2)=IN(i,5);
	OUT(2,0)=IN(i,6); OUT(2,1)=IN(i,7); OUT(2,2)=IN(i,8);
	return;
	}

	//* Converts 3x3 matrix to voigt vector form for non-symmetric tensor at specified node.
	inline void matrix_to_vector(const int i, const DENS_MAT & IN, DENS_MAT & OUT)
	{
	OUT(i,0) = IN(0,0);
	OUT(i,1) = IN(0,1);
	OUT(i,2) = IN(0,2);
	OUT(i,3) = IN(1,0);
	OUT(i,4) = IN(1,1);
	OUT(i,5) = IN(1,2);
	OUT(i,6) = IN(2,0);
	OUT(i,7) = IN(2,1);
	OUT(i,8) = IN(2,2);
	return;
	}

	//* Converts voigt vector form to 3x3 matrix for symmetric tensor at specified node.
	inline void vector_to_symm_matrix(const int i, const DENS_MAT & IN, DENS_MAT & OUT)
	{
	OUT.reset(3,3);
	OUT(0,0)=IN(i,0); OUT(0,1)=IN(i,5); OUT(0,2)=IN(i,4);
	OUT(1,0)=IN(i,5); OUT(1,1)=IN(i,1); OUT(1,2)=IN(i,3);
	OUT(2,0)=IN(i,4); OUT(2,1)=IN(i,3); OUT(2,2)=IN(i,2);
	return;
	}

	//* Converts 3x3 matrix to voigt vector form for symmetric tensor at specified node.
	inline void symm_matrix_to_vector(const int i, const DENS_MAT & IN, DENS_MAT & OUT)
	{
	OUT(i,0) = IN(0,0);
	OUT(i,1) = IN(1,1);
	OUT(i,2) = IN(1,2);
	OUT(i,3) = IN(1,2);
	OUT(i,4) = IN(0,2);
	OUT(i,5) = IN(0,1);
	return;
	}

	//* Converts voigt vector form to vector at specified node.
	inline DENS_VEC global_vector_to_vector(const int i, const DENS_MAT & IN)
	{
	DENS_VEC OUT(9);
	OUT(0)=IN(i,0); OUT(5)=IN(i,1); OUT(4)=IN(i,2);
	OUT(8)=IN(i,3); OUT(1)=IN(i,4); OUT(3)=IN(i,5);
	OUT(7)=IN(i,6); OUT(6)=IN(i,7); OUT(2)=IN(i,8);
	return OUT;
	}
	inline void vector_to_global_vector(const int i, const DENS_VEC & IN, DENS_MAT & OUT)
	{
	OUT(i,0) = IN(0);
	OUT(i,1) = IN(5);
	OUT(i,2) = IN(4);
	OUT(i,3) = IN(8);
	OUT(i,4) = IN(1);
	OUT(i,5) = IN(3);
	OUT(i,6) = IN(7);
	OUT(i,7) = IN(6);
	OUT(i,8) = IN(2);
	return;
	}

	//* Converts vector to DENS_MAT_VEC
	inline void vector_to_dens_mat_vec(const DENS_MAT & IN, DENS_MAT_VEC & OUT)
	{
	for (int i=0; i<IN.nRows(); i++) {
	for (int j=0; j<3; j++) {
	for (DENS_MAT_VEC::size_type k=0; k<3; k++) {
	OUT[k](i,j) = IN(i,3*j+k);
	}
	}
	}
	return;
	}

	//* Converts DENS_MAT_VEC to vector
	inline void symm_dens_mat_vec_to_vector(const DENS_MAT_VEC & IN, DENS_MAT & OUT)
	{
	for (int i=0; i<IN.front().nRows(); i++) {
	for (int v=0; v<6; v++) {
	OUT(i,v) = IN[voigt_idx1[v]](i,voigt_idx2[v]);
	}
	}
	return;
	}

	}
	#endif

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