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frames.hpp `- description
-------------------------
begin : June 2006
copyright : (C) 2006 Erwin Aertbelien
email : firstname.lastname@mech.kuleuven.be
History (only major changes)( AUTHOR-Description ) :
***************************************************************************
* This library is free software; you can redistribute it and/or *
* modify it under the terms of the GNU Lesser General Public *
* License as published by the Free Software Foundation; either *
* version 2.1 of the License, or (at your option) any later version. *
* *
* This library is distributed in the hope that it will be useful, *
* but WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU *
* Lesser General Public License for more details. *
* *
* You should have received a copy of the GNU Lesser General Public *
* License along with this library; if not, write to the Free Software *
* Foundation, Inc., 59 Temple Place, *
* Suite 330, Boston, MA 02111-1307 USA *
* *
***************************************************************************/
/**
* \file
* \warning
* Efficienty can be improved by writing p2 = A*(B*(C*p1))) instead of
* p2=A*B*C*p1
*
* \par PROPOSED NAMING CONVENTION FOR FRAME-like OBJECTS
*
* \verbatim
* A naming convention of objects of the type defined in this file :
* (1) Frame : F...
* Rotation : R ...
* (2) Twist : T ...
* Wrench : W ...
* Vector : V ...
* This prefix is followed by :
* for category (1) :
* F_A_B : w.r.t. frame A, frame B expressed
* ( each column of F_A_B corresponds to an axis of B,
* expressed w.r.t. frame A )
* in mathematical convention :
* A
* F_A_B == F
* B
*
* for category (2) :
* V_B : a vector expressed w.r.t. frame B
*
* This can also be prepended by a name :
* e.g. : temporaryV_B
*
* With this convention one can write :
*
* F_A_B = F_B_A.Inverse();
* F_A_C = F_A_B * F_B_C;
* V_B = F_B_C * V_C; // both translation and rotation
* V_B = R_B_C * V_C; // only rotation
* \endverbatim
*
* \par CONVENTIONS FOR WHEN USED WITH ROBOTS :
*
* \verbatim
* world : represents the frame ([1 0 0,0 1 0,0 0 1],[0 0 0]')
* mp : represents mounting plate of a robot
* (i.e. everything before MP is constructed by robot manufacturer
* everything after MP is tool )
* tf : represents task frame of a robot
* (i.e. frame in which motion and force control is expressed)
* sf : represents sensor frame of a robot
* (i.e. frame at which the forces measured by the force sensor
* are expressed )
*
* Frame F_world_mp=...;
* Frame F_mp_sf(..)
* Frame F_mp_tf(,.)
*
* Wrench are measured in sensor frame SF, so one could write :
* Wrench_tf = F_mp_tf.Inverse()* ( F_mp_sf * Wrench_sf );
* \endverbatim
*
* \par CONVENTIONS REGARDING UNITS :
* Any consistent series of units can be used, e.g. N,mm,Nmm,..mm/sec
*
* \par Twist and Wrench transformations
* 3 different types of transformations do exist for the twists
* and wrenches.
*
* \verbatim
* 1) Frame * Twist or Frame * Wrench :
* this transforms both the velocity/force reference point
* and the basis to which the twist/wrench are expressed.
* 2) Rotation * Twist or Rotation * Wrench :
* this transforms the basis to which the twist/wrench are
* expressed, but leaves the reference point intact.
* 3) Twist.RefPoint(v_base_AB) or Wrench.RefPoint(v_base_AB)
* this transforms only the reference point. v is expressed
* in the same base as the twist/wrench and points from the
* old reference point to the new reference point.
* \endverbatim
*
*\par Spatial cross products
* Let m be a 6D motion vector (Twist) and f be a 6D force vector (Wrench)
* attached to a rigid body moving with a certain velocity v (Twist). Then
*\verbatim
* 1) m_dot = v cross m or Twist=Twist*Twist
* 2) f_dot = v cross f or Wrench=Twist*Wrench
*\endverbatim
*
* \par Complexity
* Sometimes the amount of work is given in the documentation
* e.g. 6M+3A means 6 multiplications and 3 additions.
*
* \author
* Erwin Aertbelien, Div. PMA, Dep. of Mech. Eng., K.U.Leuven
*
****************************************************************************/
#ifndef KDL_FRAMES_H
#define KDL_FRAMES_H
#include "utilities/kdl-config.h"
#include "utilities/utility.h"
/////////////////////////////////////////////////////////////
namespace KDL {
class Vector;
class Rotation;
class Frame;
class Wrench;
class Twist;
class Vector2;
class Rotation2;
class Frame2;
// Equal is friend function, but default arguments for friends are forbidden (ยง8.3.6.4)
inline bool Equal(const Vector& a,const Vector& b,double eps=epsilon);
inline bool Equal(const Frame& a,const Frame& b,double eps=epsilon);
inline bool Equal(const Twist& a,const Twist& b,double eps=epsilon);
inline bool Equal(const Wrench& a,const Wrench& b,double eps=epsilon);
inline bool Equal(const Vector2& a,const Vector2& b,double eps=epsilon);
inline bool Equal(const Rotation2& a,const Rotation2& b,double eps=epsilon);
inline bool Equal(const Frame2& a,const Frame2& b,double eps=epsilon);
/**
* \brief A concrete implementation of a 3 dimensional vector class
*/
class Vector
{
public:
double data[3];
//! Does not initialise the Vector to zero. use Vector::Zero() or SetToZero for that
inline Vector() {data[0]=data[1]=data[2] = 0.0;}
//! Constructs a vector out of the three values x, y and z
inline Vector(double x,double y, double z);
//! Assignment operator. The normal copy by value semantics.
inline Vector(const Vector& arg);
//! Assignment operator. The normal copy by value semantics.
inline Vector& operator = ( const Vector& arg);
//! Access to elements, range checked when NDEBUG is not set, from 0..2
inline double operator()(int index) const;
//! Access to elements, range checked when NDEBUG is not set, from 0..2
inline double& operator() (int index);
//! Equivalent to double operator()(int index) const
double operator[] ( int index ) const
{
return this->operator() ( index );
}
//! Equivalent to double& operator()(int index)
double& operator[] ( int index )
{
return this->operator() ( index );
}
inline double x() const;
inline double y() const;
inline double z() const;
inline void x(double);
inline void y(double);
inline void z(double);
//! Reverses the sign of the Vector object itself
inline void ReverseSign();
//! subtracts a vector from the Vector object itself
inline Vector& operator-=(const Vector& arg);
//! Adds a vector from the Vector object itself
inline Vector& operator +=(const Vector& arg);
//! Scalar multiplication is defined
inline friend Vector operator*(const Vector& lhs,double rhs);
//! Scalar multiplication is defined
inline friend Vector operator*(double lhs,const Vector& rhs);
//! Scalar division is defined
inline friend Vector operator/(const Vector& lhs,double rhs);
inline friend Vector operator+(const Vector& lhs,const Vector& rhs);
inline friend Vector operator-(const Vector& lhs,const Vector& rhs);
inline friend Vector operator*(const Vector& lhs,const Vector& rhs);
inline friend Vector operator-(const Vector& arg);
inline friend double dot(const Vector& lhs,const Vector& rhs);
//! To have a uniform operator to put an element to zero, for scalar values
//! and for objects.
inline friend void SetToZero(Vector& v);
//! @return a zero vector
inline static Vector Zero();
/** Normalizes this vector and returns it norm
* makes v a unitvector and returns the norm of v.
* if v is smaller than eps, Vector(1,0,0) is returned with norm 0.
* if this is not good, check the return value of this method.
*/
double Normalize(double eps=epsilon);
//! @return the norm of the vector
double Norm() const;
//! a 3D vector where the 2D vector v is put in the XY plane
inline void Set2DXY(const Vector2& v);
//! a 3D vector where the 2D vector v is put in the YZ plane
inline void Set2DYZ(const Vector2& v);
//! a 3D vector where the 2D vector v is put in the ZX plane
inline void Set2DZX(const Vector2& v);
//! a 3D vector where the 2D vector v_XY is put in the XY plane of the frame F_someframe_XY.
inline void Set2DPlane(const Frame& F_someframe_XY,const Vector2& v_XY);
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
inline friend bool Equal(const Vector& a,const Vector& b,double eps);
//! The literal equality operator==(), also identical.
inline friend bool operator==(const Vector& a,const Vector& b);
//! The literal inequality operator!=().
inline friend bool operator!=(const Vector& a,const Vector& b);
friend class Rotation;
friend class Frame;
};
/**
\brief represents rotations in 3 dimensional space.
This class represents a rotation matrix with the following
conventions :
\verbatim
Suppose V2 = R*V, (1)
V is expressed in frame B
V2 is expressed in frame A
This matrix R consists of 3 collumns [ X,Y,Z ],
X,Y, and Z contain the axes of frame B, expressed in frame A
Because of linearity expr(1) is valid.
\endverbatim
This class only represents rotational_interpolation, not translation
Two interpretations are possible for rotation angles.
* if you rotate with angle around X frame A to have frame B,
then the result of SetRotX is equal to frame B expressed wrt A.
In code:
\verbatim
Rotation R;
F_A_B = R.SetRotX(angle);
\endverbatim
* Secondly, if you take the following code :
\verbatim
Vector p,p2; Rotation R;
R.SetRotX(angle);
p2 = R*p;
\endverbatim
then the frame p2 is rotated around X axis with (-angle).
Analogue reasonings can be applyd to SetRotY,SetRotZ,SetRot
\par type
Concrete implementation
*/
class Rotation
{
public:
double data[9];
inline Rotation() {
*this = Rotation::Identity();
}
inline Rotation(double Xx,double Yx,double Zx,
double Xy,double Yy,double Zy,
double Xz,double Yz,double Zz);
inline Rotation(const Vector& x,const Vector& y,const Vector& z);
// default copy constructor is sufficient
inline Rotation& operator=(const Rotation& arg);
//! Defines a multiplication R*V between a Rotation R and a Vector V.
//! Complexity : 9M+6A
inline Vector operator*(const Vector& v) const;
//! Access to elements 0..2,0..2, bounds are checked when NDEBUG is not set
inline double& operator()(int i,int j);
//! Access to elements 0..2,0..2, bounds are checked when NDEBUG is not set
inline double operator() (int i,int j) const;
friend Rotation operator *(const Rotation& lhs,const Rotation& rhs);
//! Sets the value of *this to its inverse.
inline void SetInverse();
//! Gives back the inverse rotation matrix of *this.
inline Rotation Inverse() const;
//! The same as R.Inverse()*v but more efficient.
inline Vector Inverse(const Vector& v) const;
//! The same as R.Inverse()*arg but more efficient.
inline Wrench Inverse(const Wrench& arg) const;
//! The same as R.Inverse()*arg but more efficient.
inline Twist Inverse(const Twist& arg) const;
//! Gives back an identity rotaton matrix
inline static Rotation Identity();
// = Rotations
//! The Rot... static functions give the value of the appropriate rotation matrix back.
inline static Rotation RotX(double angle);
//! The Rot... static functions give the value of the appropriate rotation matrix back.
inline static Rotation RotY(double angle);
//! The Rot... static functions give the value of the appropriate rotation matrix back.
inline static Rotation RotZ(double angle);
//! The DoRot... functions apply a rotation R to *this,such that *this = *this * Rot..
//! DoRot... functions are only defined when they can be executed more efficiently
inline void DoRotX(double angle);
//! The DoRot... functions apply a rotation R to *this,such that *this = *this * Rot..
//! DoRot... functions are only defined when they can be executed more efficiently
inline void DoRotY(double angle);
//! The DoRot... functions apply a rotation R to *this,such that *this = *this * Rot..
//! DoRot... functions are only defined when they can be executed more efficiently
inline void DoRotZ(double angle);
//! Along an arbitrary axes. It is not necessary to normalize rotvec.
//! returns identity rotation matrix in the case that the norm of rotvec
//! is to small to be used.
// @see Rot2 if you want to handle this error in another way.
static Rotation Rot(const Vector& rotvec,double angle);
//! Along an arbitrary axes. rotvec should be normalized.
static Rotation Rot2(const Vector& rotvec,double angle);
//! Returns a vector with the direction of the equiv. axis
//! and its norm is angle
Vector GetRot() const;
/** Returns the rotation angle around the equiv. axis
* @param axis the rotation axis is returned in this variable
* @param eps : in the case of angle == 0 : rot axis is undefined and choosen
* to be +/- Z-axis
* in the case of angle == PI : 2 solutions, positive Z-component
* of the axis is choosen.
* @result returns the rotation angle (between [0..PI] )
*/
double GetRotAngle(Vector& axis,double eps=epsilon) const;
/** Gives back a rotation matrix specified with EulerZYZ convention :
* - First rotate around Z with alfa,
* - then around the new Y with beta,
* - then around new Z with gamma.
* Invariants:
* - EulerZYX(alpha,beta,gamma) == EulerZYX(alpha +/- PHI, -beta, gamma +/- PI)
* - (angle + 2*k*PI)
**/
static Rotation EulerZYZ(double Alfa,double Beta,double Gamma);
/** Gives back the EulerZYZ convention description of the rotation matrix :
First rotate around Z with alpha,
then around the new Y with beta, then around
new Z with gamma.
Variables are bound by:
- (-PI < alpha <= PI),
- (0 <= beta <= PI),
- (-PI < gamma <= PI)
if beta==0 or beta==PI, then alpha and gamma are not unique, in this case gamma is chosen to be zero.
Invariants:
- EulerZYX(alpha,beta,gamma) == EulerZYX(alpha +/- PI, -beta, gamma +/- PI)
- angle + 2*k*PI
*/
void GetEulerZYZ(double& alpha,double& beta,double& gamma) const;
//! Gives back a rotation matrix specified with Quaternion convention
//! the norm of (x,y,z,w) should be equal to 1
static Rotation Quaternion(double x,double y,double z, double w);
//! Get the quaternion of this matrix
//! \post the norm of (x,y,z,w) is 1
void GetQuaternion(double& x,double& y,double& z, double& w) const;
/**
*
* Gives back a rotation matrix specified with RPY convention:
* first rotate around X with roll, then around the
* old Y with pitch, then around old Z with yaw
*
* Invariants:
* - RPY(roll,pitch,yaw) == RPY( roll +/- PI, PI-pitch, yaw +/- PI )
* - angles + 2*k*PI
*/
static Rotation RPY(double roll,double pitch,double yaw);
/** Gives back a vector in RPY coordinates, variables are bound by
- -PI <= roll <= PI
- -PI <= Yaw <= PI
- -PI/2 <= PITCH <= PI/2
convention :
- first rotate around X with roll,
- then around the old Y with pitch,
- then around old Z with yaw
if pitch == PI/2 or pitch == -PI/2, multiple solutions for gamma and alpha exist. The solution where roll==0
is chosen.
Invariants:
- RPY(roll,pitch,yaw) == RPY( roll +/- PI, PI-pitch, yaw +/- PI )
- angles + 2*k*PI
**/
void GetRPY(double& roll,double& pitch,double& yaw) const;
/** EulerZYX constructs a Rotation from the Euler ZYX parameters:
* - First rotate around Z with alfa,
* - then around the new Y with beta,
* - then around new X with gamma.
*
* Closely related to RPY-convention.
*
* Invariants:
* - EulerZYX(alpha,beta,gamma) == EulerZYX(alpha +/- PI, PI-beta, gamma +/- PI)
* - (angle + 2*k*PI)
**/
inline static Rotation EulerZYX(double Alfa,double Beta,double Gamma) {
return RPY(Gamma,Beta,Alfa);
}
/** GetEulerZYX gets the euler ZYX parameters of a rotation :
* First rotate around Z with alfa,
* then around the new Y with beta, then around
* new X with gamma.
*
* Range of the results of GetEulerZYX :
* - -PI <= alfa <= PI
* - -PI <= gamma <= PI
* - -PI/2 <= beta <= PI/2
*
* if beta == PI/2 or beta == -PI/2, multiple solutions for gamma and alpha exist. The solution where gamma==0
* is chosen.
*
*
* Invariants:
* - EulerZYX(alpha,beta,gamma) == EulerZYX(alpha +/- PI, PI-beta, gamma +/- PI)
* - and also (angle + 2*k*PI)
*
* Closely related to RPY-convention.
**/
inline void GetEulerZYX(double& Alfa,double& Beta,double& Gamma) const {
GetRPY(Gamma,Beta,Alfa);
}
//! Transformation of the base to which the twist is expressed.
//! Complexity : 18M+12A
//! @see Frame*Twist for a transformation that also transforms
//! the velocity reference point.
inline Twist operator * (const Twist& arg) const;
//! Transformation of the base to which the wrench is expressed.
//! Complexity : 18M+12A
//! @see Frame*Wrench for a transformation that also transforms
//! the force reference point.
inline Wrench operator * (const Wrench& arg) const;
//! Access to the underlying unitvectors of the rotation matrix
inline Vector UnitX() const {
return Vector(data[0],data[3],data[6]);
}
//! Access to the underlying unitvectors of the rotation matrix
inline void UnitX(const Vector& X) {
data[0] = X(0);
data[3] = X(1);
data[6] = X(2);
}
//! Access to the underlying unitvectors of the rotation matrix
inline Vector UnitY() const {
return Vector(data[1],data[4],data[7]);
}
//! Access to the underlying unitvectors of the rotation matrix
inline void UnitY(const Vector& X) {
data[1] = X(0);
data[4] = X(1);
data[7] = X(2);
}
//! Access to the underlying unitvectors of the rotation matrix
inline Vector UnitZ() const {
return Vector(data[2],data[5],data[8]);
}
//! Access to the underlying unitvectors of the rotation matrix
inline void UnitZ(const Vector& X) {
data[2] = X(0);
data[5] = X(1);
data[8] = X(2);
}
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
friend bool Equal(const Rotation& a,const Rotation& b,double eps);
//! The literal equality operator==(), also identical.
friend bool operator==(const Rotation& a,const Rotation& b);
//! The literal inequality operator!=()
friend bool operator!=(const Rotation& a,const Rotation& b);
friend class Frame;
};
bool operator==(const Rotation& a,const Rotation& b);
bool Equal(const Rotation& a,const Rotation& b,double eps=epsilon);
/**
\brief represents a frame transformation in 3D space (rotation + translation)
if V2 = Frame*V1 (V2 expressed in frame A, V1 expressed in frame B)
then V2 = Frame.M*V1+Frame.p
Frame.M contains columns that represent the axes of frame B wrt frame A
Frame.p contains the origin of frame B expressed in frame A.
*/
class Frame {
public:
Vector p; //!< origine of the Frame
Rotation M; //!< Orientation of the Frame
public:
inline Frame(const Rotation& R,const Vector& V);
//! The rotation matrix defaults to identity
explicit inline Frame(const Vector& V);
//! The position matrix defaults to zero
explicit inline Frame(const Rotation& R);
inline Frame() {}
//! The copy constructor. Normal copy by value semantics.
inline Frame(const Frame& arg);
//! Reads data from an double array
//\TODO should be formulated as a constructor
void Make4x4(double* d);
//! Treats a frame as a 4x4 matrix and returns element i,j
//! Access to elements 0..3,0..3, bounds are checked when NDEBUG is not set
inline double operator()(int i,int j);
//! Treats a frame as a 4x4 matrix and returns element i,j
//! Access to elements 0..3,0..3, bounds are checked when NDEBUG is not set
inline double operator() (int i,int j) const;
// = Inverse
//! Gives back inverse transformation of a Frame
inline Frame Inverse() const;
//! The same as p2=R.Inverse()*p but more efficient.
inline Vector Inverse(const Vector& arg) const;
//! The same as p2=R.Inverse()*p but more efficient.
inline Wrench Inverse(const Wrench& arg) const;
//! The same as p2=R.Inverse()*p but more efficient.
inline Twist Inverse(const Twist& arg) const;
//! Normal copy-by-value semantics.
inline Frame& operator = (const Frame& arg);
//! Transformation of the base to which the vector
//! is expressed.
inline Vector operator * (const Vector& arg) const;
//! Transformation of both the force reference point
//! and of the base to which the wrench is expressed.
//! look at Rotation*Wrench operator for a transformation
//! of only the base to which the twist is expressed.
//!
//! Complexity : 24M+18A
inline Wrench operator * (const Wrench& arg) const;
//! Transformation of both the velocity reference point
//! and of the base to which the twist is expressed.
//! look at Rotation*Twist for a transformation of only the
//! base to which the twist is expressed.
//!
//! Complexity : 24M+18A
inline Twist operator * (const Twist& arg) const;
//! Composition of two frames.
inline friend Frame operator *(const Frame& lhs,const Frame& rhs);
//! @return the identity transformation Frame(Rotation::Identity(),Vector::Zero()).
inline static Frame Identity();
//! The twist <t_this> is expressed wrt the current
//! frame. This frame is integrated into an updated frame with
//! <samplefrequency>. Very simple first order integration rule.
inline void Integrate(const Twist& t_this,double frequency);
/*
// DH_Craig1989 : constructs a transformationmatrix
// T_link(i-1)_link(i) with the Denavit-Hartenberg convention as
// described in the Craigs book: Craig, J. J.,Introduction to
// Robotics: Mechanics and Control, Addison-Wesley,
// isbn:0-201-10326-5, 1986.
//
// Note that the frame is a redundant way to express the information
// in the DH-convention.
// \verbatim
// Parameters in full : a(i-1),alpha(i-1),d(i),theta(i)
//
// axis i-1 is connected by link i-1 to axis i numbering axis 1
// to axis n link 0 (immobile base) to link n
//
// link length a(i-1) length of the mutual perpendicular line
// (normal) between the 2 axes. This normal runs from (i-1) to
// (i) axis.
//
// link twist alpha(i-1): construct plane perpendicular to the
// normal project axis(i-1) and axis(i) into plane angle from
// (i-1) to (i) measured in the direction of the normal
//
// link offset d(i) signed distance between normal (i-1) to (i)
// and normal (i) to (i+1) along axis i joint angle theta(i)
// signed angle between normal (i-1) to (i) and normal (i) to
// (i+1) along axis i
//
// First and last joints : a(0)= a(n) = 0
// alpha(0) = alpha(n) = 0
//
// PRISMATIC : theta(1) = 0 d(1) arbitrarily
//
// REVOLUTE : theta(1) arbitrarily d(1) = 0
//
// Not unique : if intersecting joint axis 2 choices for normal
// Frame assignment of the DH convention : Z(i-1) follows axis
// (i-1) X(i-1) is the normal between axis(i-1) and axis(i)
// Y(i-1) follows out of Z(i-1) and X(i-1)
//
// a(i-1) = distance from Z(i-1) to Z(i) along X(i-1)
// alpha(i-1) = angle between Z(i-1) to Z(i) along X(i-1)
// d(i) = distance from X(i-1) to X(i) along Z(i)
// theta(i) = angle between X(i-1) to X(i) along X(i)
// \endverbatim
*/
static Frame DH_Craig1989(double a,double alpha,double d,double theta);
// DH : constructs a transformationmatrix T_link(i-1)_link(i) with
// the Denavit-Hartenberg convention as described in the original
// publictation: Denavit, J. and Hartenberg, R. S., A kinematic
// notation for lower-pair mechanisms based on matrices, ASME
// Journal of Applied Mechanics, 23:215-221, 1955.
static Frame DH(double a,double alpha,double d,double theta);
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
inline friend bool Equal(const Frame& a,const Frame& b,double eps);
//! The literal equality operator==(), also identical.
inline friend bool operator==(const Frame& a,const Frame& b);
//! The literal inequality operator!=().
inline friend bool operator!=(const Frame& a,const Frame& b);
};
/**
* \brief represents both translational and rotational velocities.
*
* This class represents a twist. A twist is the combination of translational
* velocity and rotational velocity applied at one point.
*/
class Twist {
public:
Vector vel; //!< The velocity of that point
Vector rot; //!< The rotational velocity of that point.
public:
//! The default constructor initialises to Zero via the constructor of Vector.
Twist():vel(),rot() {};
Twist(const Vector& _vel,const Vector& _rot):vel(_vel),rot(_rot) {};
inline Twist& operator-=(const Twist& arg);
inline Twist& operator+=(const Twist& arg);
//! index-based access to components, first vel(0..2), then rot(3..5)
inline double& operator()(int i);
//! index-based access to components, first vel(0..2), then rot(3..5)
//! For use with a const Twist
inline double operator()(int i) const;
double operator[] ( int index ) const
{
return this->operator() ( index );
}
double& operator[] ( int index )
{
return this->operator() ( index );
}
inline friend Twist operator*(const Twist& lhs,double rhs);
inline friend Twist operator*(double lhs,const Twist& rhs);
inline friend Twist operator/(const Twist& lhs,double rhs);
inline friend Twist operator+(const Twist& lhs,const Twist& rhs);
inline friend Twist operator-(const Twist& lhs,const Twist& rhs);
inline friend Twist operator-(const Twist& arg);
inline friend double dot(const Twist& lhs,const Wrench& rhs);
inline friend double dot(const Wrench& rhs,const Twist& lhs);
inline friend void SetToZero(Twist& v);
/// Spatial cross product for 6d motion vectors, beware all of them have to be expressed in the same reference frame/point
inline friend Twist operator*(const Twist& lhs,const Twist& rhs);
/// Spatial cross product for 6d force vectors, beware all of them have to be expressed in the same reference frame/point
inline friend Wrench operator*(const Twist& lhs,const Wrench& rhs);
//! @return a zero Twist : Twist(Vector::Zero(),Vector::Zero())
static inline Twist Zero();
//! Reverses the sign of the twist
inline void ReverseSign();
//! Changes the reference point of the twist.
//! The vector v_base_AB is expressed in the same base as the twist
//! The vector v_base_AB is a vector from the old point to
//! the new point.
//!
//! Complexity : 6M+6A
inline Twist RefPoint(const Vector& v_base_AB) const;
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
inline friend bool Equal(const Twist& a,const Twist& b,double eps);
//! The literal equality operator==(), also identical.
inline friend bool operator==(const Twist& a,const Twist& b);
//! The literal inequality operator!=().
inline friend bool operator!=(const Twist& a,const Twist& b);
// = Friends
friend class Rotation;
friend class Frame;
};
/**
* \brief represents both translational and rotational acceleration.
*
* This class represents an acceleration twist. A acceleration twist is
* the combination of translational
* acceleration and rotational acceleration applied at one point.
*/
/*
class AccelerationTwist {
public:
Vector trans; //!< The translational acceleration of that point
Vector rot; //!< The rotational acceleration of that point.
public:
//! The default constructor initialises to Zero via the constructor of Vector.
AccelerationTwist():trans(),rot() {};
AccelerationTwist(const Vector& _trans,const Vector& _rot):trans(_trans),rot(_rot) {};
inline AccelerationTwist& operator-=(const AccelerationTwist& arg);
inline AccelerationTwist& operator+=(const AccelerationTwist& arg);
//! index-based access to components, first vel(0..2), then rot(3..5)
inline double& operator()(int i);
//! index-based access to components, first vel(0..2), then rot(3..5)
//! For use with a const AccelerationTwist
inline double operator()(int i) const;
double operator[] ( int index ) const
{
return this->operator() ( index );
}
double& operator[] ( int index )
{
return this->operator() ( index );
}
inline friend AccelerationTwist operator*(const AccelerationTwist& lhs,double rhs);
inline friend AccelerationTwist operator*(double lhs,const AccelerationTwist& rhs);
inline friend AccelerationTwist operator/(const AccelerationTwist& lhs,double rhs);
inline friend AccelerationTwist operator+(const AccelerationTwist& lhs,const AccelerationTwist& rhs);
inline friend AccelerationTwist operator-(const AccelerationTwist& lhs,const AccelerationTwist& rhs);
inline friend AccelerationTwist operator-(const AccelerationTwist& arg);
//inline friend double dot(const AccelerationTwist& lhs,const Wrench& rhs);
//inline friend double dot(const Wrench& rhs,const AccelerationTwist& lhs);
inline friend void SetToZero(AccelerationTwist& v);
//! @return a zero AccelerationTwist : AccelerationTwist(Vector::Zero(),Vector::Zero())
static inline AccelerationTwist Zero();
//! Reverses the sign of the AccelerationTwist
inline void ReverseSign();
//! Changes the reference point of the AccelerationTwist.
//! The vector v_base_AB is expressed in the same base as the AccelerationTwist
//! The vector v_base_AB is a vector from the old point to
//! the new point.
//!
//! Complexity : 6M+6A
inline AccelerationTwist RefPoint(const Vector& v_base_AB) const;
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
inline friend bool Equal(const AccelerationTwist& a,const AccelerationTwist& b,double eps=epsilon);
//! The literal equality operator==(), also identical.
inline friend bool operator==(const AccelerationTwist& a,const AccelerationTwist& b);
//! The literal inequality operator!=().
inline friend bool operator!=(const AccelerationTwist& a,const AccelerationTwist& b);
// = Friends
friend class Rotation;
friend class Frame;
};
*/
/**
* \brief represents the combination of a force and a torque.
*
* This class represents a Wrench. A Wrench is the force and torque applied at a point
*/
class Wrench
{
public:
Vector force; //!< Force that is applied at the origin of the current ref frame
Vector torque; //!< Torque that is applied at the origin of the current ref frame
public:
//! Does initialise force and torque to zero via the underlying constructor of Vector
Wrench():force(),torque() {};
Wrench(const Vector& _force,const Vector& _torque):force(_force),torque(_torque) {};
// = Operators
inline Wrench& operator-=(const Wrench& arg);
inline Wrench& operator+=(const Wrench& arg);
//! index-based access to components, first force(0..2), then torque(3..5)
inline double& operator()(int i);
//! index-based access to components, first force(0..2), then torque(3..5)
//! for use with a const Wrench
inline double operator()(int i) const;
double operator[] ( int index ) const
{
return this->operator() ( index );
}
double& operator[] ( int index )
{
return this->operator() ( index );
}
//! Scalar multiplication
inline friend Wrench operator*(const Wrench& lhs,double rhs);
//! Scalar multiplication
inline friend Wrench operator*(double lhs,const Wrench& rhs);
//! Scalar division
inline friend Wrench operator/(const Wrench& lhs,double rhs);
inline friend Wrench operator+(const Wrench& lhs,const Wrench& rhs);
inline friend Wrench operator-(const Wrench& lhs,const Wrench& rhs);
//! An unary - operator
inline friend Wrench operator-(const Wrench& arg);
//! Sets the Wrench to Zero, to have a uniform function that sets an object or
//! double to zero.
inline friend void SetToZero(Wrench& v);
//! @return a zero Wrench
static inline Wrench Zero();
//! Reverses the sign of the current Wrench
inline void ReverseSign();
//! Changes the reference point of the wrench.
//! The vector v_base_AB is expressed in the same base as the twist
//! The vector v_base_AB is a vector from the old point to
//! the new point.
//!
//! Complexity : 6M+6A
inline Wrench RefPoint(const Vector& v_base_AB) const;
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
inline friend bool Equal(const Wrench& a,const Wrench& b,double eps);
//! The literal equality operator==(), also identical.
inline friend bool operator==(const Wrench& a,const Wrench& b);
//! The literal inequality operator!=().
inline friend bool operator!=(const Wrench& a,const Wrench& b);
friend class Rotation;
friend class Frame;
};
//! 2D version of Vector
class Vector2
{
double data[2];
public:
//! Does not initialise to Zero().
Vector2() {data[0]=data[1] = 0.0;}
inline Vector2(double x,double y);
inline Vector2(const Vector2& arg);
inline Vector2& operator = ( const Vector2& arg);
//! Access to elements, range checked when NDEBUG is not set, from 0..1
inline double operator()(int index) const;
//! Access to elements, range checked when NDEBUG is not set, from 0..1
inline double& operator() (int index);
//! Equivalent to double operator()(int index) const
double operator[] ( int index ) const
{
return this->operator() ( index );
}
//! Equivalent to double& operator()(int index)
double& operator[] ( int index )
{
return this->operator() ( index );
}
inline double x() const;
inline double y() const;
inline void x(double);
inline void y(double);
inline void ReverseSign();
inline Vector2& operator-=(const Vector2& arg);
inline Vector2& operator +=(const Vector2& arg);
inline friend Vector2 operator*(const Vector2& lhs,double rhs);
inline friend Vector2 operator*(double lhs,const Vector2& rhs);
inline friend Vector2 operator/(const Vector2& lhs,double rhs);
inline friend Vector2 operator+(const Vector2& lhs,const Vector2& rhs);
inline friend Vector2 operator-(const Vector2& lhs,const Vector2& rhs);
inline friend Vector2 operator*(const Vector2& lhs,const Vector2& rhs);
inline friend Vector2 operator-(const Vector2& arg);
inline friend void SetToZero(Vector2& v);
//! @return a zero 2D vector.
inline static Vector2 Zero();
/** Normalizes this vector and returns it norm
* makes v a unitvector and returns the norm of v.
* if v is smaller than eps, Vector(1,0,0) is returned with norm 0.
* if this is not good, check the return value of this method.
*/
double Normalize(double eps=epsilon);
//! @return the norm of the vector
double Norm() const;
//! projects v in its XY plane, and sets *this to these values
inline void Set3DXY(const Vector& v);
//! projects v in its YZ plane, and sets *this to these values
inline void Set3DYZ(const Vector& v);
//! projects v in its ZX plane, and sets *this to these values
inline void Set3DZX(const Vector& v);
//! projects v_someframe in the XY plane of F_someframe_XY,
//! and sets *this to these values
//! expressed wrt someframe.
inline void Set3DPlane(const Frame& F_someframe_XY,const Vector& v_someframe);
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
inline friend bool Equal(const Vector2& a,const Vector2& b,double eps);
//! The literal equality operator==(), also identical.
inline friend bool operator==(const Vector2& a,const Vector2& b);
//! The literal inequality operator!=().
inline friend bool operator!=(const Vector2& a,const Vector2& b);
friend class Rotation2;
};
//! A 2D Rotation class, for conventions see Rotation. For further documentation
//! of the methods see Rotation class.
class Rotation2
{
double s,c;
//! c,s represent cos(angle), sin(angle), this also represents first col. of rot matrix
//! from outside, this class behaves as if it would store the complete 2x2 matrix.
public:
//! Default constructor does NOT initialise to Zero().
Rotation2() {c=1.0;s=0.0;}
explicit Rotation2(double angle_rad):s(sin(angle_rad)),c(cos(angle_rad)) {}
Rotation2(double ca,double sa):s(sa),c(ca){}
inline Rotation2& operator=(const Rotation2& arg);
inline Vector2 operator*(const Vector2& v) const;
//! Access to elements 0..1,0..1, bounds are checked when NDEBUG is not set
inline double operator() (int i,int j) const;
inline friend Rotation2 operator *(const Rotation2& lhs,const Rotation2& rhs);
inline void SetInverse();
inline Rotation2 Inverse() const;
inline Vector2 Inverse(const Vector2& v) const;
inline void SetIdentity();
inline static Rotation2 Identity();
//! The SetRot.. functions set the value of *this to the appropriate rotation matrix.
inline void SetRot(double angle);
//! The Rot... static functions give the value of the appropriate rotation matrix bac
inline static Rotation2 Rot(double angle);
//! Gets the angle (in radians)
inline double GetRot() const;
//! do not use operator == because the definition of Equal(.,.) is slightly
//! different. It compares whether the 2 arguments are equal in an eps-interval
inline friend bool Equal(const Rotation2& a,const Rotation2& b,double eps);
};
//! A 2D frame class, for further documentation see the Frames class
//! for methods with unchanged semantics.
class Frame2
{
public:
Vector2 p; //!< origine of the Frame
Rotation2 M; //!< Orientation of the Frame
public:
inline Frame2(const Rotation2& R,const Vector2& V);
explicit inline Frame2(const Vector2& V);
explicit inline Frame2(const Rotation2& R);
inline Frame2(void);
inline Frame2(const Frame2& arg);
inline void Make4x4(double* d);
//! Treats a frame as a 3x3 matrix and returns element i,j
//! Access to elements 0..2,0..2, bounds are checked when NDEBUG is not set
inline double operator()(int i,int j);
//! Treats a frame as a 4x4 matrix and returns element i,j
//! Access to elements 0..3,0..3, bounds are checked when NDEBUG is not set
inline double operator() (int i,int j) const;
inline void SetInverse();
inline Frame2 Inverse() const;
inline Vector2 Inverse(const Vector2& arg) const;
inline Frame2& operator = (const Frame2& arg);
inline Vector2 operator * (const Vector2& arg);
inline friend Frame2 operator *(const Frame2& lhs,const Frame2& rhs);
inline void SetIdentity();
inline void Integrate(const Twist& t_this,double frequency);
inline static Frame2 Identity() {
Frame2 tmp;
tmp.SetIdentity();
return tmp;
}
inline friend bool Equal(const Frame2& a,const Frame2& b,double eps);
};
/**
* determines the difference of vector b with vector a.
*
* see diff for Rotation matrices for further background information.
*
* \param p_w_a start vector a expressed to some frame w
* \param p_w_b end vector b expressed to some frame w .
* \param dt [optional][obsolete] time interval over which the numerical differentiation takes place.
* \return the difference (b-a) expressed to the frame w.
*/
IMETHOD Vector diff(const Vector& p_w_a,const Vector& p_w_b,double dt=1);
/**
* determines the (scaled) rotation axis necessary to rotate from b1 to b2.
*
* This rotation axis is expressed w.r.t. frame a. The rotation axis is scaled
* by the necessary rotation angle. The rotation angle is always in the
* (inclusive) interval \f$ [0 , \pi] \f$.
*
* This definition is chosen in this way to facilitate numerical differentiation.
* With this definition diff(a,b) == -diff(b,a).
*
* The diff() function is overloaded for all classes in frames.hpp and framesvel.hpp, such that
* numerical differentiation, equality checks with tolerances, etc. can be performed
* without caring exactly on which type the operation is performed.
*
* \param R_a_b1: The rotation matrix \f$ _a^{b1} R \f$ of b1 with respect to frame a.
* \param R_a_b2: The Rotation matrix \f$ _a^{b2} R \f$ of b2 with respect to frame a.
* \param dt [optional][obsolete] time interval over which the numerical differentiation takes place. By default this is set to 1.0.
* \return rotation axis to rotate from b1 to b2, scaled by the rotation angle, expressed in frame a.
* \warning - The result is not a rotational vector, i.e. it is not a mathematical vector.
* (no communitative addition).
*
* \warning - When used in the context of numerical differentiation, with the frames b1 and b2 very
* close to each other, the semantics correspond to the twist, scaled by the time.
*
* \warning - For angles equal to \f$ \pi \f$, The negative of the
* return value is equally valid.
*/
IMETHOD Vector diff(const Rotation& R_a_b1,const Rotation& R_a_b2,double dt=1);
/**
* determines the rotation axis necessary to rotate the frame b1 to the same orientation as frame b2 and the vector
* necessary to translate the origin of b1 to the origin of b2, and stores the result in a Twist datastructure.
* \param F_a_b1 frame b1 expressed with respect to some frame a.
* \param F_a_b2 frame b2 expressed with respect to some frame a.
* \warning The result is not a Twist!
* see diff() for Rotation and Vector arguments for further detail on the semantics.
*/
IMETHOD Twist diff(const Frame& F_a_b1,const Frame& F_a_b2,double dt=1);
/**
* determines the difference between two twists i.e. the difference between
* the underlying velocity vectors and rotational velocity vectors.
*/
IMETHOD Twist diff(const Twist& a,const Twist& b,double dt=1);
/**
* determines the difference between two wrenches i.e. the difference between
* the underlying torque vectors and force vectors.
*/
IMETHOD Wrench diff(const Wrench& W_a_p1,const Wrench& W_a_p2,double dt=1);
/**
* \brief adds vector da to vector a.
* see also the corresponding diff() routine.
* \param p_w_a vector a expressed to some frame w.
* \param p_w_da vector da expressed to some frame w.
* \returns the vector resulting from the displacement of vector a by vector da, expressed in the frame w.
*/
IMETHOD Vector addDelta(const Vector& p_w_a,const Vector& p_w_da,double dt=1);
/**
* returns the rotation matrix resulting from the rotation of frame a by the axis and angle
* specified with da_w.
*
* see also the corresponding diff() routine.
*
* \param R_w_a Rotation matrix of frame a expressed to some frame w.
* \param da_w axis and angle of the rotation expressed to some frame w.
* \returns the rotation matrix resulting from the rotation of frame a by the axis and angle
* specified with da. The resulting rotation matrix is expressed with respect to
* frame w.
*/
IMETHOD Rotation addDelta(const Rotation& R_w_a,const Vector& da_w,double dt=1);
/**
* returns the frame resulting from the rotation of frame a by the axis and angle
* specified in da_w and the translation of the origin (also specified in da_w).
*
* see also the corresponding diff() routine.
* \param R_w_a Rotation matrix of frame a expressed to some frame w.
* \param da_w axis and angle of the rotation (da_w.rot), together with a displacement vector for the origin (da_w.vel), expressed to some frame w.
* \returns the frame resulting from the rotation of frame a by the axis and angle
* specified with da.rot, and the translation of the origin da_w.vel . The resulting frame is expressed with respect to frame w.
*/
IMETHOD Frame addDelta(const Frame& F_w_a,const Twist& da_w,double dt=1);
/**
* \brief adds the twist da to the twist a.
* see also the corresponding diff() routine.
* \param a a twist wrt some frame
* \param da a twist difference wrt some frame
* \returns The twist (a+da) wrt the corresponding frame.
*/
IMETHOD Twist addDelta(const Twist& a,const Twist&da,double dt=1);
/**
* \brief adds the wrench da to the wrench w.
* see also the corresponding diff() routine.
* see also the corresponding diff() routine.
* \param a a wrench wrt some frame
* \param da a wrench difference wrt some frame
* \returns the wrench (a+da) wrt the corresponding frame.
*/
IMETHOD Wrench addDelta(const Wrench& a,const Wrench&da,double dt=1);
#ifdef KDL_INLINE
// #include "vector.inl"
// #include "wrench.inl"
//#include "rotation.inl"
//#include "frame.inl"
//#include "twist.inl"
//#include "vector2.inl"
//#include "rotation2.inl"
//#include "frame2.inl"
#include "frames.inl"
#endif
}
#endif
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