Metric sensitive to shape. More...

#include <TShapeNB1.hpp>

Inheritance diagram for MBMesquite::TShapeNB1:

Collaboration diagram for MBMesquite::TShapeNB1:

Public Member Functions
virtual MESQUITE_EXPORT std::string	get_name () const
virtual MESQUITE_EXPORT	~TShapeNB1 ()
virtual MESQUITE_EXPORT bool	evaluate (const MsqMatrix< 2, 2 > &T, double &result, MsqError &err)
	Evaluate \(\mu(T)\).
virtual MESQUITE_EXPORT bool	evaluate_with_grad (const MsqMatrix< 2, 2 > &T, double &result, MsqMatrix< 2, 2 > &deriv_wrt_T, MsqError &err)
	Gradient of \(\mu(T)\) with respect to components of T.
virtual MESQUITE_EXPORT bool	evaluate_with_hess (const MsqMatrix< 2, 2 > &T, double &result, MsqMatrix< 2, 2 > &deriv_wrt_T, MsqMatrix< 2, 2 > second_wrt_T[3], MsqError &err)
	Hessian of \(\mu(T)\) with respect to components of T.
virtual MESQUITE_EXPORT bool	evaluate (const MsqMatrix< 3, 3 > &T, double &result, MsqError &err)
	Evaluate \(\mu(T)\).
virtual MESQUITE_EXPORT bool	evaluate_with_grad (const MsqMatrix< 3, 3 > &T, double &result, MsqMatrix< 3, 3 > &deriv_wrt_T, MsqError &err)
	Gradient of \(\mu(T)\) with respect to components of T.
virtual MESQUITE_EXPORT bool	evaluate_with_hess (const MsqMatrix< 3, 3 > &T, double &result, MsqMatrix< 3, 3 > &deriv_wrt_T, MsqMatrix< 3, 3 > second_wrt_T[6], MsqError &err)
	Hessian of \(\mu(T)\) with respect to components of T.

Detailed Description

Metric sensitive to shape.

For 2D: \( |T - adj(T)^t |^2 = |T|^2 - 2*det(T) \)

For 3D: \( |T|^3 - 3 \sqrt{3} det(T) \)

Definition at line 47 of file TShapeNB1.hpp.

Constructor & Destructor Documentation

MBMesquite::TShapeNB1::~TShapeNB1 ( ) [virtual]

Definition at line 47 of file TShapeNB1.cpp.

{}

Member Function Documentation

bool MBMesquite::TShapeNB1::evaluate	(	const MsqMatrix< 2, 2 > &	T,
		double &	result,
		MsqError &	err
	)		`[virtual]`

Evaluate \(\mu(T)\).

Parameters:

T	2x2 relative measure matrix (typically A W^-1)
result	Output: value of function

Returns:: false if function cannot be evaluated for given T (e.g. division by zero, etc.), true otherwise.

Reimplemented from MBMesquite::TMetric.

Definition at line 49 of file TShapeNB1.cpp.

References MBMesquite::det(), and MBMesquite::sqr_Frobenius().

{
    result = sqr_Frobenius( T ) - 2.0 * det( T );
    return true;
}

bool MBMesquite::TShapeNB1::evaluate	(	const MsqMatrix< 3, 3 > &	T,
		double &	result,
		MsqError &	err
	)		`[virtual]`

Evaluate \(\mu(T)\).

Parameters:

T	3x3 relative measure matrix (typically A W^-1)
result	Output: value of function

Returns:: false if function cannot be evaluated for given T (e.g. division by zero, etc.), true otherwise.

Reimplemented from MBMesquite::TMetric.

Definition at line 82 of file TShapeNB1.cpp.

References MBMesquite::det(), MBMesquite::Frobenius(), and MBMesquite::MSQ_SQRT_THREE.

{
    double f = Frobenius( T );
    double d = det( T );
    result   = f * f * f - 3 * MSQ_SQRT_THREE * d;
    return true;
}

bool MBMesquite::TShapeNB1::evaluate_with_grad	(	const MsqMatrix< 2, 2 > &	T,
		double &	result,
		MsqMatrix< 2, 2 > &	deriv_wrt_T,
		MsqError &	err
	)		`[virtual]`

Gradient of \(\mu(T)\) with respect to components of T.

Parameters:

T	2x2 relative measure matrix (typically A W^-1)
result	Output: value of function
deriv_wrt_T	Output: partial deriviatve of \(\mu\) wrt each term of T, evaluated at passed T. \[\left[\begin{array}{cc} \frac{\partial\mu}{\partial T_{0,0}} & \frac{\partial\mu}{\partial T_{0,1}} \\ \frac{\partial\mu}{\partial T_{1,0}} & \frac{\partial\mu}{\partial T_{1,1}} \\ \end{array}\right]\]

Returns:: false if function cannot be evaluated for given T (e.g. division by zero, etc.), true otherwise.

Reimplemented from MBMesquite::TMetric.

Definition at line 55 of file TShapeNB1.cpp.

References MBMesquite::det(), MBMesquite::sqr_Frobenius(), T, and MBMesquite::transpose_adj().

{
    result      = sqr_Frobenius( T ) - 2.0 * det( T );
    deriv_wrt_T = T;
    deriv_wrt_T -= transpose_adj( T );
    deriv_wrt_T *= 2;
    return true;
}

bool MBMesquite::TShapeNB1::evaluate_with_grad	(	const MsqMatrix< 3, 3 > &	T,
		double &	result,
		MsqMatrix< 3, 3 > &	deriv_wrt_T,
		MsqError &	err
	)		`[virtual]`

Gradient of \(\mu(T)\) with respect to components of T.

Parameters:

T	3x3 relative measure matrix (typically A W^-1)
result	Output: value of function
deriv_wrt_T	Output: partial deriviatve of \(\mu\) wrt each term of T, evaluated at passed T. \[\left[\begin{array}{ccc} \frac{\partial\mu}{\partial T_{0,0}} & \frac{\partial\mu}{\partial T_{0,1}} & \frac{\partial\mu}{\partial T_{0,2}} \\ \frac{\partial\mu}{\partial T_{1,0}} & \frac{\partial\mu}{\partial T_{1,1}} & \frac{\partial\mu}{\partial T_{1,2}} \\ \frac{\partial\mu}{\partial T_{2,0}} & \frac{\partial\mu}{\partial T_{2,1}} & \frac{\partial\mu}{\partial T_{2,2}} \end{array}\right]\]

Returns:: false if function cannot be evaluated for given T (e.g. division by zero, etc.), true otherwise.

Reimplemented from MBMesquite::TMetric.

Definition at line 90 of file TShapeNB1.cpp.

References MBMesquite::det(), MBMesquite::Frobenius(), MBMesquite::MSQ_SQRT_THREE, T, and MBMesquite::transpose_adj().

{
    double f = Frobenius( T );
    double d = det( T );
    result   = f * f * f - 3 * MSQ_SQRT_THREE * d;

    deriv_wrt_T = T;
    deriv_wrt_T *= f;
    deriv_wrt_T -= MSQ_SQRT_THREE * transpose_adj( T );
    deriv_wrt_T *= 3;
    return true;
}

bool MBMesquite::TShapeNB1::evaluate_with_hess	(	const MsqMatrix< 2, 2 > &	T,
		double &	result,
		MsqMatrix< 2, 2 > &	deriv_wrt_T,
		MsqMatrix< 2, 2 >	second_wrt_T[3],
		MsqError &	err
	)		`[virtual]`

Hessian of \(\mu(T)\) with respect to components of T.

Parameters:

T	3x3 relative measure matrix (typically A W^-1)
result	Output: value of function
deriv_wrt_T	Output: partial deriviatve of \(\mu\) wrt each term of T, evaluated at passed T.
second_wrt_T	Output: 9x9 matrix of second partial deriviatve of \(\mu\) wrt each term of T, in row-major order. The symmetric matrix is decomposed into 3x3 blocks and only the upper diagonal blocks, in row-major order, are returned. \[\left[\begin{array}{cc\|cc} \frac{\partial^{2}\mu}{\partial T_{0,0}^2} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial A_{0,1}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial A_{1,0}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial A_{1,1}} \\ \frac{\partial^{2}\mu}{\partial T_{0,0}\partial A_{0,1}} & \frac{\partial^{2}\mu}{\partial T_{0,1}^2} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial A_{1,0}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial A_{1,1}} \\ \hline & & \frac{\partial^{2}\mu}{\partial T_{1,0}^2} & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial A_{1,1}} \\ & & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial A_{1,1}} & \frac{\partial^{2}\mu}{\partial T_{1,1}^2} \\ \end{array}\right]\]

Returns:: false if function cannot be evaluated for given T (e.g. division by zero, etc.), true otherwise.

Reimplemented from MBMesquite::TMetric.

Definition at line 67 of file TShapeNB1.cpp.

References MBMesquite::det(), MBMesquite::pluseq_scaled_2nd_deriv_of_det(), MBMesquite::set_scaled_I(), MBMesquite::sqr_Frobenius(), T, and MBMesquite::transpose_adj().

{
    result      = sqr_Frobenius( T ) - 2.0 * det( T );
    deriv_wrt_T = T;
    deriv_wrt_T -= transpose_adj( T );
    deriv_wrt_T *= 2;
    set_scaled_I( second_wrt_T, 2.0 );
    pluseq_scaled_2nd_deriv_of_det( second_wrt_T, -2.0 );
    return true;
}

bool MBMesquite::TShapeNB1::evaluate_with_hess	(	const MsqMatrix< 3, 3 > &	T,
		double &	result,
		MsqMatrix< 3, 3 > &	deriv_wrt_T,
		MsqMatrix< 3, 3 >	second_wrt_T[6],
		MsqError &	err
	)		`[virtual]`

Hessian of \(\mu(T)\) with respect to components of T.

Parameters:

T	3x3 relative measure matrix (typically A W^-1)
result	Output: value of function
deriv_wrt_T	Output: partial deriviatve of \(\mu\) wrt each term of T, evaluated at passed T.
second_wrt_T	Output: 9x9 matrix of second partial deriviatve of \(\mu\) wrt each term of T, in row-major order. The symmetric matrix is decomposed into 3x3 blocks and only the upper diagonal blocks, in row-major order, are returned. \[\left[\begin{array}{ccc\|ccc\|ccc} \frac{\partial^{2}\mu}{\partial T_{0,0}^2} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{0,1}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{0,2}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{1,0}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{1,1}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{1,2}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{2,0}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{2,2}} \\ \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{0,1}} & \frac{\partial^{2}\mu}{\partial T_{0,1}^2} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{0,2}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{1,0}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{1,1}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{1,2}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{2,0}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{2,2}} \\ \frac{\partial^{2}\mu}{\partial T_{0,0}\partial T_{0,2}} & \frac{\partial^{2}\mu}{\partial T_{0,1}\partial T_{0,2}} & \frac{\partial^{2}\mu}{\partial T_{0,2}^2} & \frac{\partial^{2}\mu}{\partial T_{0,2}\partial T_{1,0}} & \frac{\partial^{2}\mu}{\partial T_{0,2}\partial T_{1,1}} & \frac{\partial^{2}\mu}{\partial T_{0,2}\partial T_{1,2}} & \frac{\partial^{2}\mu}{\partial T_{0,2}\partial T_{2,0}} & \frac{\partial^{2}\mu}{\partial T_{0,2}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{0,2}\partial T_{2,2}} \\ \hline & & & \frac{\partial^{2}\mu}{\partial T_{1,0}^2} & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial T_{1,1}} & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial T_{1,2}} & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial T_{2,0}} & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial T_{2,2}} \\ & & & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial T_{1,1}} & \frac{\partial^{2}\mu}{\partial T_{1,1}^2} & \frac{\partial^{2}\mu}{\partial T_{1,1}\partial T_{1,2}} & \frac{\partial^{2}\mu}{\partial T_{1,1}\partial T_{2,0}} & \frac{\partial^{2}\mu}{\partial T_{1,1}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{1,1}\partial T_{2,2}} \\ & & & \frac{\partial^{2}\mu}{\partial T_{1,0}\partial T_{1,2}} & \frac{\partial^{2}\mu}{\partial T_{1,1}\partial T_{1,2}} & \frac{\partial^{2}\mu}{\partial T_{1,2}^2} & \frac{\partial^{2}\mu}{\partial T_{1,2}\partial T_{2,0}} & \frac{\partial^{2}\mu}{\partial T_{1,2}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{1,2}\partial T_{2,2}} \\ \hline & & & & & & \frac{\partial^{2}\mu}{\partial T_{2,0}^2} & \frac{\partial^{2}\mu}{\partial T_{2,0}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{2,0}\partial T_{2,2}} \\ & & & & & & \frac{\partial^{2}\mu}{\partial T_{2,0}\partial T_{2,1}} & \frac{\partial^{2}\mu}{\partial T_{2,1}^2} & \frac{\partial^{2}\mu}{\partial T_{2,1}\partial T_{2,2}} \\ & & & & & & \frac{\partial^{2}\mu}{\partial T_{2,0}\partial T_{2,2}} & \frac{\partial^{2}\mu}{\partial T_{2,1}\partial T_{2,2}} & \frac{\partial^{2}\mu}{\partial T_{2,2}^2} \\ \end{array}\right]\]

Returns:: false if function cannot be evaluated for given T (e.g. division by zero, etc.), true otherwise.

Reimplemented from MBMesquite::TMetric.

Definition at line 106 of file TShapeNB1.cpp.

References MBMesquite::det(), MBMesquite::Frobenius(), MBMesquite::MSQ_SQRT_THREE, MBMesquite::pluseq_scaled_I(), MBMesquite::pluseq_scaled_outer_product(), MBMesquite::set_scaled_2nd_deriv_of_det(), T, and MBMesquite::transpose_adj().

{
    double f = Frobenius( T );
    double d = det( T );
    result   = f * f * f - 3 * MSQ_SQRT_THREE * d;

    deriv_wrt_T = T;
    deriv_wrt_T *= f;
    deriv_wrt_T -= MSQ_SQRT_THREE * transpose_adj( T );
    deriv_wrt_T *= 3;

    set_scaled_2nd_deriv_of_det( second_wrt_T, -3 * MSQ_SQRT_THREE, T );
    if( f > 1e-50 )
        pluseq_scaled_outer_product( second_wrt_T, 3.0 / f, T );
    else
        std::cout << "Warning: Division by zero avoided in TShapeNB1::evaluate_with_hess()" << std::endl;
    pluseq_scaled_I( second_wrt_T, 3.0 * f );
    return true;
}

std::string MBMesquite::TShapeNB1::get_name ( ) const [virtual]

Reimplemented from MBMesquite::TMetricNonBarrier.

Definition at line 42 of file TShapeNB1.cpp.

{
    return "TShapeNB1";
}

List of all members.

The documentation for this class was generated from the following files:

Public Member Functions

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation