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vpSimulatorAfma6 Class Reference

#include <visp3/robot/vpSimulatorAfma6.h>

+ Inheritance diagram for vpSimulatorAfma6:

Public Types

enum  vpDisplayRobotType { MODEL_3D, MODEL_DH }
 
enum  vpRobotStateType { STATE_STOP, STATE_VELOCITY_CONTROL, STATE_POSITION_CONTROL, STATE_ACCELERATION_CONTROL }
 
enum  vpControlFrameType { REFERENCE_FRAME, ARTICULAR_FRAME, CAMERA_FRAME, MIXT_FRAME }
 
enum  vpAfma6ToolType {
  TOOL_CCMOP, TOOL_GRIPPER, TOOL_VACUUM, TOOL_GENERIC_CAMERA,
  TOOL_CUSTOM
}
 

Public Member Functions

 vpSimulatorAfma6 ()
 
 vpSimulatorAfma6 (bool display)
 
virtual ~vpSimulatorAfma6 ()
 
void getCameraParameters (vpCameraParameters &cam, const unsigned int &image_width, const unsigned int &image_height)
 
void getCameraParameters (vpCameraParameters &cam, const vpImage< unsigned char > &I)
 
void getCameraParameters (vpCameraParameters &cam, const vpImage< vpRGBa > &I)
 
void getDisplacement (const vpRobot::vpControlFrameType frame, vpColVector &displacement)
 
void getPosition (const vpRobot::vpControlFrameType frame, vpColVector &q)
 
void getPosition (const vpRobot::vpControlFrameType frame, vpColVector &q, double &timestamp)
 
void getPosition (const vpRobot::vpControlFrameType frame, vpPoseVector &position)
 
void getPosition (const vpRobot::vpControlFrameType frame, vpPoseVector &position, double &timestamp)
 
double getPositioningVelocity (void)
 
void getVelocity (const vpRobot::vpControlFrameType frame, vpColVector &q)
 
void getVelocity (const vpRobot::vpControlFrameType frame, vpColVector &q, double &timestamp)
 
vpColVector getVelocity (const vpRobot::vpControlFrameType frame)
 
vpColVector getVelocity (const vpRobot::vpControlFrameType frame, double &timestamp)
 
void get_cMe (vpHomogeneousMatrix &cMe)
 
void get_cVe (vpVelocityTwistMatrix &cVe)
 
void get_eJe (vpMatrix &eJe)
 
void get_fJe (vpMatrix &fJe)
 
void init (vpAfma6::vpAfma6ToolType tool, vpCameraParameters::vpCameraParametersProjType projModel=vpCameraParameters::perspectiveProjWithoutDistortion)
 
bool initialiseCameraRelativeToObject (const vpHomogeneousMatrix &cMo)
 
void initialiseObjectRelativeToCamera (const vpHomogeneousMatrix &cMo)
 
void move (const char *filename)
 
void setCameraParameters (const vpCameraParameters &cam)
 
void setJointLimit (const vpColVector &limitMin, const vpColVector &limitMax)
 
void setPosition (const vpRobot::vpControlFrameType frame, const vpColVector &q)
 
void setPosition (const vpRobot::vpControlFrameType frame, const double pos1, const double pos2, const double pos3, const double pos4, const double pos5, const double pos6)
 
void setPosition (const char *filename)
 
void setPositioningVelocity (const double vel)
 
bool setPosition (const vpHomogeneousMatrix &cdMo, vpImage< unsigned char > *Iint=NULL, const double &errMax=0.001)
 
vpRobot::vpRobotStateType setRobotState (const vpRobot::vpRobotStateType newState)
 
void setVelocity (const vpRobot::vpControlFrameType frame, const vpColVector &velocity)
 
void stopMotion ()
 
Inherited functionalities from vpRobotWireFrameSimulator
vpCameraParameters getExternalCameraParameters () const
 
vpHomogeneousMatrix getExternalCameraPosition () const
 
void getInternalView (vpImage< vpRGBa > &I)
 
void getInternalView (vpImage< unsigned char > &I)
 
vpHomogeneousMatrix get_cMo ()
 
vpHomogeneousMatrix get_fMo () const
 
void initScene (const vpSceneObject &obj, const vpSceneDesiredObject &desiredObject)
 
void initScene (const char *obj, const char *desiredObject)
 
void initScene (const vpSceneObject &obj)
 
void initScene (const char *obj)
 
void setCameraColor (const vpColor col)
 
void setConstantSamplingTimeMode (const bool _constantSamplingTimeMode)
 
void setCurrentViewColor (const vpColor col)
 
void setDesiredViewColor (const vpColor col)
 
void setDesiredCameraPosition (const vpHomogeneousMatrix cdMo_)
 
void setDisplayRobotType (const vpDisplayRobotType dispType)
 
void setExternalCameraPosition (const vpHomogeneousMatrix camMf_)
 
void setGraphicsThickness (unsigned int thickness)
 
void setSamplingTime (const double &delta_t)
 
void setSingularityManagement (const bool sm)
 
void setVerbose (bool verbose)
 
void set_fMo (const vpHomogeneousMatrix &fMo_)
 
Inherited functionalities from vpRobotSimulator
double getSamplingTime () const
 
Inherited functionalities from vpRobot
double getMaxTranslationVelocity (void) const
 
double getMaxRotationVelocity (void) const
 
vpColVector getPosition (const vpRobot::vpControlFrameType frame)
 
virtual vpRobotStateType getRobotState (void) const
 
void setMaxRotationVelocity (const double maxVr)
 
void setMaxTranslationVelocity (const double maxVt)
 
Inherited functionalities from vpAfma6
void init (const std::string &camera_extrinsic_parameters)
 
void init (const std::string &camera_extrinsic_parameters, const std::string &camera_intrinsic_parameters)
 
void init (vpAfma6::vpAfma6ToolType tool, const std::string &filename)
 
void init (vpAfma6::vpAfma6ToolType tool, const vpHomogeneousMatrix &eMc_)
 
vpHomogeneousMatrix getForwardKinematics (const vpColVector &q) const
 
int getInverseKinematics (const vpHomogeneousMatrix &fMc, vpColVector &q, const bool &nearest=true, const bool &verbose=false) const
 
vpHomogeneousMatrix get_eMc () const
 
vpHomogeneousMatrix get_fMc (const vpColVector &q) const
 
void get_fMc (const vpColVector &q, vpHomogeneousMatrix &fMc) const
 
void get_fMe (const vpColVector &q, vpHomogeneousMatrix &fMe) const
 
void get_cMe (vpHomogeneousMatrix &cMe) const
 
void get_cVe (vpVelocityTwistMatrix &cVe) const
 
void get_eJe (const vpColVector &q, vpMatrix &eJe) const
 
void get_fJe (const vpColVector &q, vpMatrix &fJe) const
 
vpAfma6ToolType getToolType () const
 
vpCameraParameters::vpCameraParametersProjType getCameraParametersProjType () const
 
void getCameraParameters (vpCameraParameters &cam, const unsigned int &image_width, const unsigned int &image_height) const
 
void getCameraParameters (vpCameraParameters &cam, const vpImage< unsigned char > &I) const
 
void getCameraParameters (vpCameraParameters &cam, const vpImage< vpRGBa > &I) const
 
vpColVector getJointMin () const
 
vpColVector getJointMax () const
 
double getCoupl56 () const
 
double getLong56 () const
 
void parseConfigFile (const std::string &filename)
 
virtual void set_eMc (const vpHomogeneousMatrix &eMc)
 

Static Public Member Functions

static bool readPosFile (const std::string &filename, vpColVector &q)
 
static bool savePosFile (const std::string &filename, const vpColVector &q)
 
Static Public Member Functions inherited from vpRobot
static vpColVector saturateVelocities (const vpColVector &v_in, const vpColVector &v_max, bool verbose=false)
 

Public Attributes

vpImage< vpRGBaI
 

Static Public Attributes

static const double defaultPositioningVelocity = 25.0
 
static const std::string CONST_AFMA6_FILENAME
 
static const std::string CONST_EMC_CCMOP_WITHOUT_DISTORTION_FILENAME
 
static const std::string CONST_EMC_CCMOP_WITH_DISTORTION_FILENAME
 
static const std::string CONST_EMC_GRIPPER_WITHOUT_DISTORTION_FILENAME
 
static const std::string CONST_EMC_GRIPPER_WITH_DISTORTION_FILENAME
 
static const std::string CONST_EMC_VACUUM_WITHOUT_DISTORTION_FILENAME
 
static const std::string CONST_EMC_VACUUM_WITH_DISTORTION_FILENAME
 
static const std::string CONST_EMC_GENERIC_WITHOUT_DISTORTION_FILENAME
 
static const std::string CONST_EMC_GENERIC_WITH_DISTORTION_FILENAME
 
static const std::string CONST_CAMERA_AFMA6_FILENAME
 
static const char *const CONST_CCMOP_CAMERA_NAME = "Dragonfly2-8mm-ccmop"
 
static const char *const CONST_GRIPPER_CAMERA_NAME = "Dragonfly2-6mm-gripper"
 
static const char *const CONST_VACUUM_CAMERA_NAME = "Dragonfly2-6mm-vacuum"
 
static const char *const CONST_GENERIC_CAMERA_NAME = "Generic-camera"
 
static const vpAfma6ToolType defaultTool = TOOL_CCMOP
 
static const unsigned int njoint = 6
 

Protected Types

enum  vpSceneObject {
  THREE_PTS, CUBE, PLATE, SMALL_PLATE,
  RECTANGLE, SQUARE_10CM, DIAMOND, TRAPEZOID,
  THREE_LINES, ROAD, TIRE, PIPE,
  CIRCLE, SPHERE, CYLINDER, PLAN,
  POINT_CLOUD
}
 
enum  vpSceneDesiredObject { D_STANDARD, D_CIRCLE, D_TOOL }
 
enum  vpCameraTrajectoryDisplayType { CT_LINE, CT_POINT }
 

Protected Member Functions

Protected Member Functions Inherited from vpSimulatorAfma6
void computeArticularVelocity ()
 
void compute_fMi ()
 
void findHighestPositioningSpeed (vpColVector &q)
 
void getExternalImage (vpImage< vpRGBa > &I)
 
void get_fMi (vpHomogeneousMatrix *fMit)
 
void init ()
 
void initArms ()
 
void initDisplay ()
 
int isInJointLimit (void)
 
bool singularityTest (const vpColVector q, vpMatrix &J)
 
void updateArticularPosition ()
 
Protected Member Functions Inherited from vpWireFrameSimulator
void display_scene (Matrix mat, Bound_scene &sc, const vpImage< vpRGBa > &I, const vpColor &color)
 
void display_scene (Matrix mat, Bound_scene &sc, const vpImage< unsigned char > &I, const vpColor &color)
 
vpHomogeneousMatrix navigation (const vpImage< vpRGBa > &I, bool &changed)
 
vpHomogeneousMatrix navigation (const vpImage< unsigned char > &I, bool &changed)
 
vpImagePoint projectCameraTrajectory (const vpImage< vpRGBa > &I, const vpHomogeneousMatrix &cMo, const vpHomogeneousMatrix &fMo)
 
vpImagePoint projectCameraTrajectory (const vpImage< unsigned char > &I, const vpHomogeneousMatrix &cMo, const vpHomogeneousMatrix &fMo)
 
vpImagePoint projectCameraTrajectory (const vpImage< vpRGBa > &I, const vpHomogeneousMatrix &cMo, const vpHomogeneousMatrix &fMo, const vpHomogeneousMatrix &cMf)
 
vpImagePoint projectCameraTrajectory (const vpImage< unsigned char > &I, const vpHomogeneousMatrix &cMo, const vpHomogeneousMatrix &fMo, const vpHomogeneousMatrix &cMf)
 
Protected Member Functions Inherited from vpRobot
vpControlFrameType setRobotFrame (vpRobot::vpControlFrameType newFrame)
 
vpControlFrameType getRobotFrame (void) const
 
Protected Member Functions Inherited from vpAfma6
void setToolType (vpAfma6::vpAfma6ToolType tool)
 

Protected Attributes

double tcur
 
double tprev
 
Bound_scene * robotArms
 
unsigned int size_fMi
 
vpHomogeneousMatrixfMi
 
vpColVector artCoord
 
vpColVector artVel
 
vpColVector velocity
 
pthread_t thread
 
pthread_attr_t attr
 
pthread_mutex_t mutex_fMi
 
pthread_mutex_t mutex_artVel
 
pthread_mutex_t mutex_artCoord
 
pthread_mutex_t mutex_velocity
 
pthread_mutex_t mutex_display
 
bool displayBusy
 
bool robotStop
 
bool jointLimit
 
unsigned int jointLimitArt
 
bool singularityManagement
 
vpCameraParameters cameraParam
 
vpDisplayX display
 
vpDisplayRobotType displayType
 
bool displayAllowed
 
bool constantSamplingTimeMode
 
bool setVelocityCalled
 
bool verbose_
 
Bound_scene scene
 
Bound_scene desiredScene
 
Bound_scene camera
 
std::list< vpImageSimulatorobjectImage
 
vpHomogeneousMatrix fMo
 
vpHomogeneousMatrix fMc
 
vpHomogeneousMatrix camMf
 
vpHomogeneousMatrix refMo
 
vpHomogeneousMatrix cMo
 
vpHomogeneousMatrix cdMo
 
vpSceneObject object
 
vpSceneDesiredObject desiredObject
 
vpColor camColor
 
vpColor camTrajColor
 
vpColor curColor
 
vpColor desColor
 
bool sceneInitialized
 
bool displayCameraTrajectory
 
std::list< vpImagePointcameraTrajectory
 
std::list< vpHomogeneousMatrixposeList
 
std::list< vpHomogeneousMatrixfMoList
 
unsigned int nbrPtLimit
 
vpImagePoint old_iPr
 
vpImagePoint old_iPz
 
vpImagePoint old_iPt
 
bool blockedr
 
bool blockedz
 
bool blockedt
 
bool blocked
 
vpHomogeneousMatrix camMf2
 
vpHomogeneousMatrix f2Mf
 
double px_int
 
double py_int
 
double px_ext
 
double py_ext
 
bool displayObject
 
bool displayDesiredObject
 
bool displayCamera
 
bool displayImageSimulator
 
float cameraFactor
 
vpCameraTrajectoryDisplayType camTrajType
 
bool extCamChanged
 
vpHomogeneousMatrix rotz
 
unsigned int thickness_
 
double delta_t_
 
double maxTranslationVelocity
 
double maxRotationVelocity
 
int nDof
 
vpMatrix eJe
 
int eJeAvailable
 
vpMatrix fJe
 
int fJeAvailable
 
int areJointLimitsAvailable
 
double * qmin
 
double * qmax
 
double _coupl_56
 
double _long_56
 
double _joint_max [6]
 
double _joint_min [6]
 
vpTranslationVector _etc
 
vpRxyzVector _erc
 
vpHomogeneousMatrix _eMc
 
vpAfma6ToolType tool_current
 
vpCameraParameters::vpCameraParametersProjType projModel
 

Static Protected Attributes

static const double maxTranslationVelocityDefault = 0.2
 
static const double maxRotationVelocityDefault = 0.7
 

Protected Member Functions Inherited from vpRobotWireFrameSimulator

vpColVector get_artCoord ()
 
void set_artCoord (const vpColVector &coord)
 
vpColVector get_artVel ()
 
void set_artVel (const vpColVector &vel)
 
vpColVector get_velocity ()
 
void set_velocity (const vpColVector &vel)
 
void set_displayBusy (const bool &status)
 
bool get_displayBusy ()
 
static void * launcher (void *arg)
 

Inherited functionalities from vpWireFrameSimulator

void getExternalImage (vpImage< unsigned char > &I)
 
void getExternalImage (vpImage< unsigned char > &I, const vpHomogeneousMatrix &camMf)
 
void getExternalImage (vpImage< vpRGBa > &I, const vpHomogeneousMatrix &camMf)
 
vpCameraParameters getExternalCameraParameters (const vpImage< unsigned char > &I) const
 
vpCameraParameters getExternalCameraParameters (const vpImage< vpRGBa > &I) const
 
vpHomogeneousMatrix get_cMo () const
 
void initScene (const vpSceneObject &obj, const vpSceneDesiredObject &desiredObject, const std::list< vpImageSimulator > &imObj)
 
void initScene (const char *obj, const char *desiredObject, const std::list< vpImageSimulator > &imObj)
 
void initScene (const vpSceneObject &obj, const std::list< vpImageSimulator > &imObj)
 
void initScene (const char *obj, const std::list< vpImageSimulator > &imObj)
 
void setCameraColor (const vpColor &col)
 
void setCurrentViewColor (const vpColor &col)
 
void setDesiredViewColor (const vpColor &col)
 
void setDesiredCameraPosition (const vpHomogeneousMatrix &cdMo_)
 
void setExternalCameraPosition (const vpHomogeneousMatrix &cam_Mf)
 
void deleteCameraPositionHistory ()
 
void displayTrajectory (const vpImage< unsigned char > &I, const std::list< vpHomogeneousMatrix > &list_cMo, const std::list< vpHomogeneousMatrix > &list_fMo, const vpHomogeneousMatrix &camMf)
 
void displayTrajectory (const vpImage< vpRGBa > &I, const std::list< vpHomogeneousMatrix > &list_cMo, const std::list< vpHomogeneousMatrix > &list_fMo, const vpHomogeneousMatrix &camMf)
 
vpCameraParameters getInternalCameraParameters (const vpImage< unsigned char > &I) const
 
vpCameraParameters getInternalCameraParameters (const vpImage< vpRGBa > &I) const
 
void getInternalImage (vpImage< unsigned char > &I)
 
void getInternalImage (vpImage< vpRGBa > &I)
 
void get_cMo_History (std::list< vpHomogeneousMatrix > &cMo_history)
 
void get_fMo_History (std::list< vpHomogeneousMatrix > &fMo_history)
 
void setCameraPositionRelObj (const vpHomogeneousMatrix &cMo_)
 
void setCameraPositionRelWorld (const vpHomogeneousMatrix &fMc_)
 
void setCameraSizeFactor (const float factor)
 
void setCameraTrajectoryColor (const vpColor &col)
 
void setCameraTrajectoryDisplayType (const vpCameraTrajectoryDisplayType &camTraj_type)
 
void setDisplayCameraTrajectory (const bool &do_display)
 
void setExternalCameraParameters (const vpCameraParameters &cam)
 
void setInternalCameraParameters (const vpCameraParameters &cam)
 
void setNbPtTrajectory (const unsigned int nbPt)
 

Detailed Description

Simulator of Irisa's gantry robot named Afma6.

Implementation of the vpRobotWireFrameSimulator class in order to simulate Irisa's Afma6 robot. This robot is a gantry robot with six degrees of freedom manufactured in 1992 by the french Afma-Robots company.

Warning
This class uses threading capabilities. Thus on Unix-like platforms, the libpthread third-party library need to be installed. On Windows, we use the native threading capabilities.

This class allows to control the Afma6 gantry robot in position and velocity:

All the translations are expressed in meters for positions and m/s for the velocities. Rotations are expressed in radians for the positions, and rad/s for the rotation velocities.

The direct and inverse kinematics models are implemented in the vpAfma6 class.

To control the robot in position, you may set the controller to position control and then send the position to reach in a specific frame like here in the joint space:

#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
#include <visp3/core/vpMath.h>
int main()
{
// Set a joint position
q[0] = 0.1; // Joint 1 position, in meter
q[1] = 0.2; // Joint 2 position, in meter
q[2] = 0.3; // Joint 3 position, in meter
q[3] = M_PI/8; // Joint 4 position, in rad
q[4] = M_PI/4; // Joint 5 position, in rad
q[5] = M_PI; // Joint 6 position, in rad
// Initialize the controller to position control
// Moves the robot in the joint space
return 0;
}

To control the robot in velocity, you may set the controller to velocity control and then send the velocities. To end the velocity control and stop the robot you have to set the controller to the stop state. Here is an example of a velocity control in the joint space:

#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
#include <visp3/core/vpMath.h>
int main()
{
vpColVector qvel(6);
// Set a joint velocity
qvel[0] = 0.1; // Joint 1 velocity in m/s
qvel[1] = 0.1; // Joint 2 velocity in m/s
qvel[2] = 0.1; // Joint 3 velocity in m/s
qvel[3] = M_PI/8; // Joint 4 velocity in rad/s
qvel[4] = 0; // Joint 5 velocity in rad/s
qvel[5] = 0; // Joint 6 velocity in rad/s
// Initialize the controller to position control
for ( ; ; ) {
// Apply a velocity in the joint space
// Compute new velocities qvel...
}
// Stop the robot
return 0;
}

It is also possible to measure the robot current position with getPosition() method and the robot current velocities with the getVelocity() method.

For convenience, there is also the ability to read/write joint positions from a position file with readPosFile() and savePosFile() methods.

To know how this class can be used to achieve a visual servoing simulation, you can follow the Tutorial: Image-based visual servo.

Examples:
servoMomentPoints.cpp, servoMomentPolygon.cpp, servoSimuAfma6FourPoints2DCamVelocity.cpp, and tutorial-ibvs-4pts-wireframe-robot-afma6.cpp.

Definition at line 176 of file vpSimulatorAfma6.h.

Member Enumeration Documentation

enum vpAfma6::vpAfma6ToolType
inherited

List of possible tools that can be attached to the robot end-effector.

Enumerator
TOOL_CCMOP 

Pneumatic CCMOP gripper.

TOOL_GRIPPER 

Pneumatic gripper with 2 fingers.

TOOL_VACUUM 

Pneumatic vaccum gripper.

TOOL_GENERIC_CAMERA 

A generic camera.

TOOL_CUSTOM 

A user defined tool.

Definition at line 115 of file vpAfma6.h.

Enumerator
CT_LINE 
CT_POINT 

Definition at line 183 of file vpWireFrameSimulator.h.

Robot control frames.

Enumerator
REFERENCE_FRAME 

Corresponds to a fixed reference frame attached to the robot structure.

ARTICULAR_FRAME 

Corresponds to the joint space.

CAMERA_FRAME 

Corresponds to a frame attached to the camera mounted on the robot end-effector.

MIXT_FRAME 

Corresponds to a "virtual" frame where translations are expressed in the reference frame, and rotations in the camera frame.

Definition at line 76 of file vpRobot.h.

Enumerator
MODEL_3D 
MODEL_DH 

Definition at line 89 of file vpRobotWireFrameSimulator.h.

enum vpRobot::vpRobotStateType
inherited

Robot control states.

Enumerator
STATE_STOP 

Stops robot motion especially in velocity and acceleration control.

STATE_VELOCITY_CONTROL 

Initialize the velocity controller.

STATE_POSITION_CONTROL 

Initialize the position controller.

STATE_ACCELERATION_CONTROL 

Initialize the acceleration controller.

Definition at line 64 of file vpRobot.h.

Type of scene used to display the object at the desired pose (in the internal view).

  • D_STANDARD will use the vpSceneObject used to be the object at the current position.
  • D_OUTIL will display a tool which is attached to the camera.
Enumerator
D_STANDARD 

The object displayed at the desired position is the same than the scene object defined in vpSceneObject.

D_CIRCLE 

The object displayed at the desired position is a circle.

D_TOOL 

A cylindrical tool is attached to the camera.

Definition at line 176 of file vpWireFrameSimulator.h.

Type of scene used to display the object at the current position.

Enumerator
THREE_PTS 

A 40cm by 40cm plate with 3 points at coordinates (0,0,0), (0.1,0,0), (0,0.1,0). Each point is represented by a circle with 2cm radius.

CUBE 

A 12.5cm size cube.

PLATE 

A 40cm by 40cm plate with 4 points at coordinates (-0.1,-0.1,0), (0.1,-0.1,0), (0.1,0.1,0), (0.1,0.1,0). Each point is represented by a circle with 2cm radius.

SMALL_PLATE 

4 points at coordinates (-0.03,-0.03,0), (0.03,-0.03,0), (0.03,0.03,0), (0.03,0.03,0). Each point is represented by a circle with 1cm radius.

RECTANGLE 

A 40cm by 40cm plate with 4 points at coordinates (-0.07,-0.05,0), (0.07,0.05,0), (0.07,-0.05,0), (-0.07,-0.05,0). Each point is represented by a circle with 2cm radius.

SQUARE_10CM 

A 40cm by 40cm plate with 4 points at coordinates (-0.05,0.05,0), (0.05,0.05,0), (0.05,-0.05,0), (-0.05,-0.05,0). Each point is represented by a circle with 2cm radius.

DIAMOND 

A 40cm by 40cm plate with 4 points at coordinates (0,-0.1,0), (0.1,0,0), (0,0.1,0), (-0.1,0,0). Each point is represented by a circle with 2cm radius.

TRAPEZOID 

A 40cm by 40cm plate with 4 points at coordinates (-0.025,-0.05,0), (-0.075,0.05,0), (0.075,0.05,0), (0.025,-0.05,0). Each point is represented by a circle with 2cm radius.

THREE_LINES 

Three parallel lines with equation y=-5, y=0, y=5.

ROAD 

Three parallel lines representing a road.

TIRE 

A tire represented by 2 circles with radius 10cm and 15cm.

PIPE 

A pipe represented by a cylinder of 25 cm length and 15cm radius.

CIRCLE 

A 10cm radius circle.

SPHERE 

A 15cm radius sphere.

CYLINDER 

A cylinder of 80cm length and 10cm radius.

PLAN 

A plane represented by a 56cm by 56cm plate with a grid of 49 squares inside.

POINT_CLOUD 

A plate with 8 points at coordinates (0.05,0,0), (0.15,0.05,0), (0.2,0.2,0), (-0.05,0.2,0), (-0.15,-0.1,0), (-0.1,-0.1,0), (-0.05,0.05,0) and (0.5,0,0). ach point is represented by a circle with 2cm radius.

Definition at line 149 of file vpWireFrameSimulator.h.

Constructor & Destructor Documentation

vpSimulatorAfma6::vpSimulatorAfma6 ( bool  do_display)

Member Function Documentation

void vpSimulatorAfma6::compute_fMi ( )
protected

Compute the pose between the robot reference frame and the frames used used to compute the Denavit-Hartenberg representation. The last element of the table corresponds to the pose between the reference frame and the camera frame.

To compute the diferent homogeneous matrices, this function needs the articular coordinates as input.

Finally the output is a table of 8 elements : $ fM1 $, $ fM2 $, $ fM3 $, $ fM4 $, $ fM5 $, $ fM6 = fMw $, $ fM7 = fMe $ and $ fMc $ - where w is for wrist and e for effector-.

Definition at line 650 of file vpSimulatorAfma6.cpp.

References vpAfma6::_long_56, vpRobotWireFrameSimulator::fMi, vpRobotWireFrameSimulator::get_artCoord(), vpAfma6::get_fMc(), and vpRobotWireFrameSimulator::mutex_fMi.

Referenced by initialiseCameraRelativeToObject(), updateArticularPosition(), and vpSimulatorAfma6().

void vpWireFrameSimulator::deleteCameraPositionHistory ( )
inlineinherited

Delete the history of the main camera position which are displayed in the external views.

Definition at line 261 of file vpWireFrameSimulator.h.

void vpWireFrameSimulator::display_scene ( Matrix  mat,
Bound_scene &  sc,
const vpImage< unsigned char > &  I,
const vpColor color 
)
protectedinherited
void vpWireFrameSimulator::displayTrajectory ( const vpImage< unsigned char > &  I,
const std::list< vpHomogeneousMatrix > &  list_cMo,
const std::list< vpHomogeneousMatrix > &  list_fMo,
const vpHomogeneousMatrix cMf 
)
inherited

Display a trajectory thanks to a list of homogeneous matrices which give the position of the camera relative to the object and the position of the object relative to the world reference frame. The trajectory is projected into the view of an external camera whose position is given in parameter.

The two lists must have the same size of homogeneous matrices must have the same size.

Parameters
I: The image where the trajectory is displayed.
list_cMo: The homogeneous matrices list containing the position of the camera relative to the object.
list_fMo: The homogeneous matrices list containing the position of the object relative to the world reference frame.
cMf: A homogeneous matrix which gives the position of the external camera (used to project the trajectory) relative to the world reference frame.

Definition at line 1204 of file vpWireFrameSimulator.cpp.

References vpWireFrameSimulator::camTrajColor, vpWireFrameSimulator::camTrajType, vpWireFrameSimulator::CT_LINE, vpWireFrameSimulator::CT_POINT, vpException::dimensionError, vpDisplay::displayLine(), vpDisplay::displayPoint(), vpWireFrameSimulator::projectCameraTrajectory(), vpWireFrameSimulator::rotz, and vpWireFrameSimulator::thickness_.

void vpWireFrameSimulator::displayTrajectory ( const vpImage< vpRGBa > &  I,
const std::list< vpHomogeneousMatrix > &  list_cMo,
const std::list< vpHomogeneousMatrix > &  list_fMo,
const vpHomogeneousMatrix cMf 
)
inherited

Display a trajectory thanks to a list of homogeneous matrices which give the position of the camera relative to the object and the position of the object relative to the world reference frame. The trajectory is projected into the view of an external camera whose position is given in parameter.

The two lists must have the same size of homogeneous matrices must have the same size.

Parameters
I: The image where the trajectory is displayed.
list_cMo: The homogeneous matrices list containing the position of the camera relative to the object.
list_fMo: The homogeneous matrices list containing the position of the object relative to the world reference frame.
cMf: A homogeneous matrix which gives the position of the external camera (used to project the trajectory) relative to the world reference frame.

Definition at line 1244 of file vpWireFrameSimulator.cpp.

References vpWireFrameSimulator::camTrajColor, vpWireFrameSimulator::camTrajType, vpWireFrameSimulator::CT_LINE, vpWireFrameSimulator::CT_POINT, vpException::dimensionError, vpDisplay::displayLine(), vpDisplay::displayPoint(), vpWireFrameSimulator::projectCameraTrajectory(), vpWireFrameSimulator::rotz, and vpWireFrameSimulator::thickness_.

void vpSimulatorAfma6::findHighestPositioningSpeed ( vpColVector q)
protected
vpColVector vpRobotWireFrameSimulator::get_artVel ( )
inlineprotectedinherited
void vpAfma6::get_cMe ( vpHomogeneousMatrix cMe) const
inherited

Get the geometric transformation between the camera frame and the end-effector frame. This transformation is constant and correspond to the extrinsic camera parameters estimated by calibration.

Parameters
cMe: Transformation between the camera frame and the end-effector frame.

Definition at line 839 of file vpAfma6.cpp.

References vpAfma6::_eMc, and vpHomogeneousMatrix::inverse().

Referenced by get_cMe(), vpRobotAfma6::get_cMe(), vpAfma6::get_cVe(), get_cVe(), and vpRobotAfma6::get_cVe().

void vpSimulatorAfma6::get_cMe ( vpHomogeneousMatrix cMe)

Get the geometric transformation $^c{\bf M}_e$ between the camera frame and the end-effector frame. This transformation is constant and correspond to the extrinsic camera parameters estimated by calibration.

Parameters
cMe: Transformation between the camera frame and the end-effector frame.

Definition at line 2225 of file vpSimulatorAfma6.cpp.

References vpAfma6::get_cMe().

Referenced by getExternalImage().

vpHomogeneousMatrix vpRobotWireFrameSimulator::get_cMo ( )
inherited

Get the pose between the object and the robot's camera.

Returns
The pose between the object and the fixed world frame.

Definition at line 363 of file vpRobotWireFrameSimulator.cpp.

References vpWireFrameSimulator::fMo, vpRobotWireFrameSimulator::get_fMi(), vpHomogeneousMatrix::inverse(), and vpRobotWireFrameSimulator::size_fMi.

Referenced by setPosition().

vpHomogeneousMatrix vpWireFrameSimulator::get_cMo ( ) const
inlineinherited

Get the pose between the object and the camera.

Returns
The pose between between the object and the camera.

Definition at line 366 of file vpWireFrameSimulator.h.

void vpWireFrameSimulator::get_cMo_History ( std::list< vpHomogeneousMatrix > &  cMo_history)
inlineinherited

Get the homogeneous matrices cMo stored to display the camera trajectory.

Parameters
cMo_history: The list of the homogeneous matrices cMo.

Definition at line 373 of file vpWireFrameSimulator.h.

void vpAfma6::get_cVe ( vpVelocityTwistMatrix cVe) const
inherited

Get the twist transformation from camera frame to end-effector frame. This transformation allows to compute a velocity expressed in the end-effector frame into the camera frame.

Parameters
cVe: Twist transformation.

Definition at line 869 of file vpAfma6.cpp.

References vpVelocityTwistMatrix::buildFrom(), and vpAfma6::get_cMe().

void vpSimulatorAfma6::get_cVe ( vpVelocityTwistMatrix cVe)

Get the twist transformation $^c{\bf V}_e$ from camera frame to end-effector frame. This transformation allows to compute a velocity expressed in the end-effector frame into the camera frame.

Parameters
cVe: Twist transformation.

Definition at line 2238 of file vpSimulatorAfma6.cpp.

References vpVelocityTwistMatrix::buildFrom(), and vpAfma6::get_cMe().

bool vpRobotWireFrameSimulator::get_displayBusy ( )
inlineprotectedinherited
void vpAfma6::get_eJe ( const vpColVector q,
vpMatrix eJe 
) const
inherited

Get the robot jacobian expressed in the end-effector frame.

Parameters
q: Articular joint position of the robot. q[0], q[1], q[2] correspond to the first 3 translations expressed in meter, while q[3], q[4] and q[5] correspond to the 3 succesives rotations expressed in radians.
eJe: Robot jacobian expressed in the end-effector frame.

Definition at line 892 of file vpAfma6.cpp.

References vpAfma6::_coupl_56, vpAfma6::_long_56, and vpArray2D< Type >::resize().

Referenced by computeArticularVelocity(), get_eJe(), vpRobotAfma6::get_eJe(), and getVelocity().

void vpSimulatorAfma6::get_eJe ( vpMatrix eJe_)
virtual

Get the robot jacobian expressed in the end-effector frame.

To compute $^e{\bf J}_e$, we communicate with the low level controller to get the joint position of the robot.

Parameters
eJe_: Robot jacobian $^e{\bf J}_e$ expressed in the end-effector frame.

Implements vpRobot.

Definition at line 2256 of file vpSimulatorAfma6.cpp.

References vpRobotWireFrameSimulator::get_artCoord(), vpAfma6::get_eJe(), and vpERROR_TRACE.

vpHomogeneousMatrix vpAfma6::get_eMc ( ) const
inherited

Get the geometric transformation between the end-effector frame and the camera or tool frame. This transformation is constant and correspond to the extrinsic camera parameters estimated by calibration.

Returns
Transformation between the end-effector frame and the camera frame.

Definition at line 854 of file vpAfma6.cpp.

References vpAfma6::_eMc.

void vpAfma6::get_fJe ( const vpColVector q,
vpMatrix fJe 
) const
inherited

Get the robot jacobian expressed in the robot reference frame also called fix frame.

\[ {^f}J_e = \left(\begin{array}{cccccc} 1 & 0 & 0 & -Ls4 & 0 & 0 \\ 0 & 1 & 0 & Lc4 & 0 & 0 \\ 0 & 0 & 1 & 0 & 0 & 0 \\ 0 & 0 & 0 & 0 & c4+\gamma s4c5 & -s4c5 \\ 0 & 0 & 0 & 0 & s4-\gamma c4c5 & c4c5 \\ 0 & 0 & 0 & 1 & -gamma s5 & s5 \\ \end{array} \right) \]

where $\gamma$ is the coupling factor between join 5 and 6.

Parameters
q: Articular joint position of the robot. q[0], q[1], q[2] correspond to the first 3 translations expressed in meter, while q[3], q[4] and q[5] correspond to the 3 succesives rotations expressed in radians.
fJe: Robot jacobian expressed in the robot reference frame.

Definition at line 961 of file vpAfma6.cpp.

References vpAfma6::_coupl_56, vpAfma6::_long_56, and vpArray2D< Type >::resize().

Referenced by computeArticularVelocity(), get_fJe(), vpRobotAfma6::get_fJe(), and getVelocity().

void vpSimulatorAfma6::get_fJe ( vpMatrix fJe_)
virtual

Get the robot jacobian expressed in the robot reference frame also called fix frame.

To compute $^f{\bf J}_e$, we communicate with the low level controller to get the joint position of the robot.

Parameters
fJe_: Robot jacobian $^f{\bf J}_e$ expressed in the reference frame.

Implements vpRobot.

Definition at line 2280 of file vpSimulatorAfma6.cpp.

References vpRobotWireFrameSimulator::get_artCoord(), vpAfma6::get_fJe(), and vpERROR_TRACE.

vpHomogeneousMatrix vpAfma6::get_fMc ( const vpColVector q) const
inherited

Compute the forward kinematics (direct geometric model) as an homogeneous matrix.

By forward kinematics we mean here the position and the orientation of the camera relative to the base frame given the articular positions of all the six joints.

This method is the same than getForwardKinematics(const vpColVector & q).

Parameters
q: Articular position of the six joints: q[0], q[1], q[2] correspond to the first 3 translations expressed in meter, while q[3], q[4] and q[5] correspond to the 3 succesives rotations expressed in radians.
Returns
The homogeneous matrix corresponding to the direct geometric model which expresses the transformation between the base frame and the camera frame (fMc).
See Also
getForwardKinematics(const vpColVector & q)
Examples:
testRobotAfma6Pose.cpp.

Definition at line 723 of file vpAfma6.cpp.

Referenced by compute_fMi(), vpRobotAfma6::getDisplacement(), vpAfma6::getForwardKinematics(), getPosition(), vpRobotAfma6::getPosition(), vpRobotAfma6::getVelocity(), setPosition(), and vpRobotAfma6::setPosition().

void vpAfma6::get_fMc ( const vpColVector q,
vpHomogeneousMatrix fMc 
) const
inherited

Compute the forward kinematics (direct geometric model) as an homogeneous matrix.

By forward kinematics we mean here the position and the orientation of the camera relative to the base frame given the articular positions of all the six joints.

Parameters
q: Articular joint position of the robot. q[0], q[1], q[2] correspond to the first 3 translations expressed in meter, while q[3], q[4] and q[5] correspond to the 3 succesives rotations expressed in radians.
fMcThe homogeneous matrix corresponding to the direct geometric model which expresses the transformation between the fix frame and the camera frame (fMc).

Definition at line 751 of file vpAfma6.cpp.

References vpAfma6::_eMc, and vpAfma6::get_fMe().

void vpAfma6::get_fMe ( const vpColVector q,
vpHomogeneousMatrix fMe 
) const
inherited

Compute the forward kinematics (direct geometric model) as an homogeneous matrix.

By forward kinematics we mean here the position and the orientation of the end effector with respect to the base frame given the articular positions of all the six joints.

Parameters
q: Articular joint position of the robot. q[0], q[1], q[2] correspond to the first 3 translations expressed in meter, while q[3], q[4] and q[5] correspond to the 3 succesives rotations expressed in radians.
fMeThe homogeneous matrix corresponding to the direct geometric model which expresses the transformation between the fix frame and the end effector frame (fMe).

Definition at line 785 of file vpAfma6.cpp.

References vpAfma6::_coupl_56, and vpAfma6::_long_56.

Referenced by vpAfma6::get_fMc().

void vpSimulatorAfma6::get_fMi ( vpHomogeneousMatrix fMit)
inlineprotectedvirtual

Get a table of poses between the reference frame and the frames you used to compute the Denavit-Hartenberg representation

Implements vpRobotWireFrameSimulator.

Definition at line 256 of file vpSimulatorAfma6.h.

Referenced by getExternalImage(), initialiseObjectRelativeToCamera(), and updateArticularPosition().

vpHomogeneousMatrix vpRobotWireFrameSimulator::get_fMo ( ) const
inlineinherited

Get the pose between the object and the fixed world frame.

Returns
The pose between the object and the fixed world frame.

Definition at line 242 of file vpRobotWireFrameSimulator.h.

References vpWireFrameSimulator::fMo.

void vpWireFrameSimulator::get_fMo_History ( std::list< vpHomogeneousMatrix > &  fMo_history)
inlineinherited

Get the homogeneous matrices fMo stored to display the camera trajectory.

Parameters
fMo_history: The list of the homogeneous matrices fMo.

Definition at line 392 of file vpWireFrameSimulator.h.

vpColVector vpRobotWireFrameSimulator::get_velocity ( )
inlineprotectedinherited
void vpAfma6::getCameraParameters ( vpCameraParameters cam,
const unsigned int &  image_width,
const unsigned int &  image_height 
) const
inherited

Get the current intrinsic camera parameters obtained by calibration.

Warning
This method needs XML library to parse the file defined in vpAfma6::CONST_CAMERA_AFMA6_FILENAME and containing the camera parameters. If XML is detected by ViSP, VISP_HAVE_XML2 macro is defined in include/visp3/core/vpConfig.h file.
Thid method needs also an access to the files containing the camera parameters in XML format. This access is available if VISP_HAVE_AFMA6_DATA macro is defined in include/visp3/core/vpConfig.h file.
  • If VISP_HAVE_AFMA6_DATA and VISP_HAVE_XML2 macros are defined, this method gets the camera parameters from const_camera_Afma6.xml config file.
  • If these two macros are not defined, this method set the camera parameters to default one.
Parameters
cam: In output, camera parameters to fill.
image_width: Image width used to compute camera calibration.
image_height: Image height used to compute camera calibration.

The code below shows how to get the camera parameters of the camera attached to the robot.

#include <visp3/core/vpImage.h>
#include <visp3/sensor/vp1394TwoGrabber.h>
#include <visp3/robot/vpRobotAfma6.h>
#include <visp3/core/vpCameraParameters.h>
int main()
{
#if defined(VISP_HAVE_DC1394) && defined(VISP_HAVE_AFMA6)
// Acquire an image to update image structure
g.acquire(I) ;
vpRobotAfma6 robot;
// Get the intrinsic camera parameters depending on the image size
// Camera parameters are read from
// /udd/fspindle/robot/Afma6/current/include/const_camera_Afma6.xml
// if VISP_HAVE_AFMA6_DATA and VISP_HAVE_XML2 macros are defined in vpConfig.h file
try {
robot.getCameraParameters (cam, I.getWidth(), I.getHeight());
}
catch(...) {
std::cout << "Cannot get camera parameters for image: " << I.getWidth() << " x " << I.getHeight() << std::endl;
}
std::cout << "Camera parameters: " << cam << std::endl;
#endif
}
Exceptions
vpRobotException::readingParametersError: If the camera parameters are not found.
Examples:
servoAfma62DhalfCamVelocity.cpp, servoAfma6Cylinder2DCamVelocity.cpp, servoAfma6Cylinder2DCamVelocitySecondaryTask.cpp, servoAfma6Ellipse2DCamVelocity.cpp, servoAfma6FourPoints2DArtVelocity.cpp, servoAfma6FourPoints2DCamVelocityInteractionCurrent.cpp, servoAfma6FourPoints2DCamVelocityInteractionDesired.cpp, servoAfma6Line2DCamVelocity.cpp, servoAfma6Point2DArtVelocity.cpp, servoAfma6Point2DCamVelocity.cpp, servoAfma6Points2DCamVelocityEyeToHand.cpp, servoAfma6Segment2DCamVelocity.cpp, servoAfma6SquareLines2DCamVelocity.cpp, servoAfma6TwoLines2DCamVelocity.cpp, testAfma6.cpp, testRobotAfma6.cpp, and testRobotAfma6Pose.cpp.

Definition at line 1235 of file vpAfma6.cpp.

References vpAfma6::CONST_CAMERA_AFMA6_FILENAME, vpAfma6::CONST_CCMOP_CAMERA_NAME, vpAfma6::CONST_GENERIC_CAMERA_NAME, vpAfma6::CONST_GRIPPER_CAMERA_NAME, vpAfma6::CONST_VACUUM_CAMERA_NAME, vpAfma6::getToolType(), vpCameraParameters::initPersProjWithDistortion(), vpCameraParameters::initPersProjWithoutDistortion(), vpXmlParserCamera::parse(), vpCameraParameters::perspectiveProjWithDistortion, vpCameraParameters::perspectiveProjWithoutDistortion, vpAfma6::projModel, vpRobotException::readingParametersError, vpXmlParserCamera::SEQUENCE_OK, vpAfma6::TOOL_CCMOP, vpAfma6::TOOL_GENERIC_CAMERA, vpAfma6::TOOL_GRIPPER, vpAfma6::TOOL_VACUUM, vpERROR_TRACE, and vpTRACE.

Referenced by vpAfma6::getCameraParameters().

void vpAfma6::getCameraParameters ( vpCameraParameters cam,
const vpImage< unsigned char > &  I 
) const
inherited

Get the current intrinsic camera parameters obtained by calibration.

Camera parameters are read from /udd/fspindle/robot/Afma6/current/include/const_camera_Afma6.xml

Parameters
cam: In output, camera parameters to fill.
I: A B&W image send by the current camera in use.
#include <visp3/core/vpImage.h>
#include <visp3/sensor/vp1394TwoGrabber.h>
#include <visp3/robot/vpRobotAfma6.h>
#include <visp3/core/vpCameraParameters.h>
int main()
{
#if defined(VISP_HAVE_DC1394) && defined(VISP_HAVE_AFMA6)
// Acquire an image to update image structure
g.acquire(I) ;
vpRobotAfma6 robot;
// Get the intrinsic camera parameters depending on the image size
try {
robot.getCameraParameters (cam, I);
}
catch(...) {
std::cout << "Cannot get camera parameters for image: " << I.getWidth() << " x " << I.getHeight() << std::endl;
}
std::cout << "Camera parameters: " << cam << std::endl;
#endif
}
Exceptions
vpRobotException::readingParametersError: If the camera parameters are not found.

Definition at line 1453 of file vpAfma6.cpp.

References vpAfma6::getCameraParameters(), vpImage< Type >::getHeight(), and vpImage< Type >::getWidth().

void vpAfma6::getCameraParameters ( vpCameraParameters cam,
const vpImage< vpRGBa > &  I 
) const
inherited

Get the current intrinsic camera parameters obtained by calibration.

Camera parameters are read from /udd/fspindle/robot/Afma6/current/include/const_camera_Afma6.xml

Parameters
cam: In output, camera parameters to fill.
I: A color image send by the current camera in use.
#include <visp3/core/vpConfig.h>
#include <visp3/core/vpImage.h>
#include <visp3/sensor/vp1394TwoGrabber.h>
#include <visp3/robot/vpRobotAfma6.h>
#include <visp3/core/vpCameraParameters.h>
int main()
{
#if defined(VISP_HAVE_DC1394) && defined(VISP_HAVE_AFMA6)
// Acquire an image to update image structure
g.acquire(I) ;
vpRobotAfma6 robot;
// Get the intrinsic camera parameters depending on the image size
try {
robot.getCameraParameters (cam, I);
}
catch(...) {
std::cout << "Cannot get camera parameters for image: " << I.getWidth() << " x " << I.getHeight() << std::endl;
}
std::cout << "Camera parameters: " << cam << std::endl;
#endif
}
Exceptions
vpRobotException::readingParametersError: If the camera parameters are not found.

Definition at line 1502 of file vpAfma6.cpp.

References vpAfma6::getCameraParameters(), vpImage< Type >::getHeight(), and vpImage< Type >::getWidth().

void vpSimulatorAfma6::getCameraParameters ( vpCameraParameters cam,
const unsigned int &  image_width,
const unsigned int &  image_height 
)

Get the current intrinsic camera parameters obtained by calibration.

Parameters
cam: In output, camera parameters to fill.
image_width: Image width used to compute camera calibration.
image_height: Image height used to compute camera calibration.
Warning
The image size must be : 640x480 !

Definition at line 424 of file vpSimulatorAfma6.cpp.

References vpAfma6::CONST_CCMOP_CAMERA_NAME, vpAfma6::CONST_GRIPPER_CAMERA_NAME, vpAfma6::getToolType(), vpCameraParameters::initPersProjWithoutDistortion(), vpWireFrameSimulator::px_int, vpWireFrameSimulator::py_int, vpAfma6::TOOL_CCMOP, vpAfma6::TOOL_CUSTOM, vpAfma6::TOOL_GENERIC_CAMERA, vpAfma6::TOOL_GRIPPER, vpAfma6::TOOL_VACUUM, vpERROR_TRACE, and vpTRACE.

Referenced by getCameraParameters(), and initDisplay().

void vpSimulatorAfma6::getCameraParameters ( vpCameraParameters cam,
const vpImage< unsigned char > &  I_ 
)

Get the current intrinsic camera parameters obtained by calibration.

Parameters
cam: In output, camera parameters to fill.
I_: A B&W image send by the current camera in use.
Warning
The image size must be : 640x480 !

Definition at line 481 of file vpSimulatorAfma6.cpp.

References getCameraParameters(), vpImage< Type >::getHeight(), and vpImage< Type >::getWidth().

void vpSimulatorAfma6::getCameraParameters ( vpCameraParameters cam,
const vpImage< vpRGBa > &  I_ 
)

Get the current intrinsic camera parameters obtained by calibration.

Parameters
cam: In output, camera parameters to fill.
I_: A B&W image send by the current camera in use.
Warning
The image size must be : 640x480 !

Definition at line 496 of file vpSimulatorAfma6.cpp.

References getCameraParameters(), vpImage< Type >::getHeight(), and vpImage< Type >::getWidth().

vpCameraParameters::vpCameraParametersProjType vpAfma6::getCameraParametersProjType ( ) const
inlineinherited

Get the current camera model projection type.

Definition at line 162 of file vpAfma6.h.

double vpAfma6::getCoupl56 ( ) const
inherited

Return the coupling factor between join 5 and 6.

Returns
Coupling factor between join 5 and 6.

Definition at line 1035 of file vpAfma6.cpp.

References vpAfma6::_coupl_56.

void vpSimulatorAfma6::getDisplacement ( const vpRobot::vpControlFrameType  frame,
vpColVector displacement 
)
virtual

Get the robot displacement since the last call of this method.

Warning
This functionnality is not implemented for the moment in the cartesian space. It is only available in the joint space (vpRobot::ARTICULAR_FRAME).
Parameters
frame: The frame in which the measured displacement is expressed.
displacement: The measured displacement since the last call of this method. The dimension of displacement is always
  1. Translations are expressed in meters, rotations in radians.

In camera or reference frame, rotations are expressed with the Euler Rxyz representation.

See Also
getArticularDisplacement(), getCameraDisplacement()

Implements vpRobot.

Definition at line 1985 of file vpSimulatorAfma6.cpp.

References vpRobot::ARTICULAR_FRAME, vpRobot::CAMERA_FRAME, vpRobotWireFrameSimulator::get_artCoord(), vpRobot::MIXT_FRAME, vpRobot::REFERENCE_FRAME, and vpColVector::resize().

vpCameraParameters vpRobotWireFrameSimulator::getExternalCameraParameters ( ) const
inlineinherited

Get the parameters of the virtual external camera.

Returns
It returns the camera parameters.

Definition at line 211 of file vpRobotWireFrameSimulator.h.

References vpImage< Type >::getHeight(), vpImage< Type >::getWidth(), vpMath::maximum(), and vpMath::minimum().

vpCameraParameters vpWireFrameSimulator::getExternalCameraParameters ( const vpImage< unsigned char > &  I) const
inlineinherited

Get the parameters of the virtual external camera.

Parameters
I: The image used to display the view of the camera.
Returns
It returns the camera parameters.

Definition at line 276 of file vpWireFrameSimulator.h.

References vpImage< Type >::getHeight(), vpImage< Type >::getWidth(), vpMath::maximum(), and vpMath::minimum().

Referenced by vpWireFrameSimulator::projectCameraTrajectory().

vpCameraParameters vpWireFrameSimulator::getExternalCameraParameters ( const vpImage< vpRGBa > &  I) const
inlineinherited

Get the parameters of the virtual external camera.

Parameters
I: The image used to display the view of the camera.
Returns
It returns the camera parameters.

Definition at line 295 of file vpWireFrameSimulator.h.

References vpImage< Type >::getHeight(), vpImage< Type >::getWidth(), vpMath::maximum(), and vpMath::minimum().

vpHomogeneousMatrix vpRobotWireFrameSimulator::getExternalCameraPosition ( ) const
inlineinherited

Get the external camera's position relative to the the world reference frame.

Returns
the main external camera position relative to the the world reference frame.

Definition at line 228 of file vpRobotWireFrameSimulator.h.

References vpWireFrameSimulator::getExternalCameraPosition().

Referenced by updateArticularPosition(), and vpSimulatorViper850::updateArticularPosition().

void vpWireFrameSimulator::getExternalImage ( vpImage< unsigned char > &  I)
inherited

Get the external view. It corresponds to the view of the scene from a reference frame you have to set.

Parameters
I: The image where the external view is displayed.
Warning
: The objects are displayed thanks to overlays. The image I is not modified.
Examples:
servoSimu4Points.cpp, servoSimuCylinder.cpp, servoSimuSphere.cpp, tutorial-ibvs-4pts-wireframe-camera.cpp, and wireframeSimulator.cpp.

Definition at line 999 of file vpWireFrameSimulator.cpp.

References vpWireFrameSimulator::camColor, vpWireFrameSimulator::camera, vpWireFrameSimulator::cameraTrajectory, vpWireFrameSimulator::camMf, vpWireFrameSimulator::camMf2, vpWireFrameSimulator::camTrajColor, vpWireFrameSimulator::camTrajType, vpWireFrameSimulator::cMo, vpWireFrameSimulator::CT_LINE, vpWireFrameSimulator::CT_POINT, vpWireFrameSimulator::CUBE, vpWireFrameSimulator::curColor, vpImage< Type >::display, vpDisplay::display(), vpWireFrameSimulator::display_scene(), vpWireFrameSimulator::displayCamera, vpWireFrameSimulator::displayCameraTrajectory, vpWireFrameSimulator::displayImageSimulator, vpDisplay::displayLine(), vpWireFrameSimulator::displayObject, vpDisplay::displayPoint(), vpWireFrameSimulator::extCamChanged, vpWireFrameSimulator::f2Mf, vpWireFrameSimulator::fMc, vpWireFrameSimulator::fMo, vpWireFrameSimulator::fMoList, vpImage< Type >::getHeight(), vpImageSimulator::getImage(), vpWireFrameSimulator::getInternalCameraParameters(), vpImage< Type >::getWidth(), vpHomogeneousMatrix::inverse(), vpMath::maximum(), vpMath::minimum(), vpWireFrameSimulator::navigation(), vpWireFrameSimulator::nbrPtLimit, vpWireFrameSimulator::objectImage, vpWireFrameSimulator::poseList, vpWireFrameSimulator::projectCameraTrajectory(), vpWireFrameSimulator::px_ext, vpWireFrameSimulator::py_ext, vpWireFrameSimulator::rotz, vpWireFrameSimulator::scene, vpImageSimulator::setCameraPosition(), vpWireFrameSimulator::SPHERE, and vpWireFrameSimulator::thickness_.

void vpWireFrameSimulator::getExternalImage ( vpImage< unsigned char > &  I,
const vpHomogeneousMatrix cam_Mf 
)
inherited
void vpWireFrameSimulator::getExternalImage ( vpImage< vpRGBa > &  I,
const vpHomogeneousMatrix cam_Mf 
)
inherited
vpHomogeneousMatrix vpAfma6::getForwardKinematics ( const vpColVector q) const
inherited

Compute the forward kinematics (direct geometric model) as an homogeneous matrix.

By forward kinematics we mean here the position and the orientation of the camera relative to the base frame given the articular positions of all the six joints.

This method is the same than get_fMc(const vpColVector & q).

Parameters
q: Articular position of the six joints: q[0], q[1], q[2] correspond to the first 3 translations expressed in meter, while q[3], q[4] and q[5] correspond to the 3 succesives rotations expressed in radians.
Returns
The homogeneous matrix corresponding to the direct geometric model which expresses the transformation between the base frame and the camera frame (fMc).
See Also
get_fMc(const vpColVector & q)
getInverseKinematics()

Definition at line 460 of file vpAfma6.cpp.

References vpAfma6::get_fMc().

vpCameraParameters vpWireFrameSimulator::getInternalCameraParameters ( const vpImage< unsigned char > &  I) const
inlineinherited

Get the parameters of the virtual internal camera.

Parameters
I: The image used to display the view of the camera.
Returns
It returns the camera parameters.

Definition at line 326 of file vpWireFrameSimulator.h.

References vpImage< Type >::getHeight(), vpImage< Type >::getWidth(), vpMath::maximum(), and vpMath::minimum().

Referenced by vpWireFrameSimulator::getExternalImage(), and vpWireFrameSimulator::getInternalImage().

vpCameraParameters vpWireFrameSimulator::getInternalCameraParameters ( const vpImage< vpRGBa > &  I) const
inlineinherited

Get the parameters of the virtual internal camera.

Parameters
I: The image used to display the view of the camera.
Returns
It returns the camera parameters.

Definition at line 345 of file vpWireFrameSimulator.h.

References vpImage< Type >::getHeight(), vpImage< Type >::getWidth(), vpMath::maximum(), and vpMath::minimum().

int vpAfma6::getInverseKinematics ( const vpHomogeneousMatrix fMc,
vpColVector q,
const bool &  nearest = true,
const bool &  verbose = false 
) const
inherited

Compute the inverse kinematics (inverse geometric model).

By inverse kinematics we mean here the six articular values of the joint positions given the position and the orientation of the camera frame relative to the base frame.

Parameters
fMc: Homogeneous matrix describing the transformation from base frame to the camera frame.
q: In input, the current articular joint position of the robot. In output, the solution of the inverse kinematics. Articular position of the six joints: q[0], q[1], q[2] correspond to the first 3 translations expressed in meter, while q[3], q[4] and q[5] correspond to the 3 succesives rotations expressed in radians.
nearest: true to return the nearest solution to q. false to return the farest.
verbose: Activates printings when no solution is found.
Returns
The number of solutions (1 or 2) of the inverse geometric model. O, if no solution can be found.

The code below shows how to compute the inverse geometric model:

#include <visp3/core/vpConfig.h>
#include <visp3/core/vpColVector.h>
#include <visp3/core/vpHomogeneousMatrix.h>
#include <visp3/robot/vpRobotAfma6.h>
int main()
{
#ifdef VISP_HAVE_AFMA6
vpColVector q1(6), q2(6);
vpRobotAfma6 robot;
// Get the current articular position of the robot
// Compute the pose of the camera in the reference frame using the
// direct geometric model
fMc = robot.getForwardKinematics(q1);
// this is similar to fMc = robot.get_fMc(q1);
// or robot.get_fMc(q1, fMc);
// Compute the inverse geometric model
int nbsol; // number of solutions (0, 1 or 2) of the inverse geometric model
// get the nearest solution to the current articular position
nbsol = robot.getInverseKinematics(fMc, q1, true);
if (nbsol == 0)
std::cout << "No solution of the inverse geometric model " << std::endl;
else if (nbsol >= 1)
std::cout << "First solution: " << q1 << std::endl;
if (nbsol == 2) {
// Compute the other solution of the inverse geometric model
q2 = q1;
robot.getInverseKinematics(fMc, q2, false);
std::cout << "Second solution: " << q2 << std::endl;
}
#endif
}
See Also
getForwardKinematics()

Definition at line 542 of file vpAfma6.cpp.

References vpAfma6::_coupl_56, vpAfma6::_eMc, vpAfma6::_joint_max, vpAfma6::_joint_min, vpAfma6::_long_56, vpMath::deg(), vpArray2D< Type >::getRows(), vpHomogeneousMatrix::inverse(), vpAfma6::njoint, vpMath::rad(), vpColVector::resize(), and vpTRACE.

Referenced by initialiseCameraRelativeToObject(), setPosition(), and vpRobotAfma6::setPosition().

vpColVector vpAfma6::getJointMax ( ) const
inherited

Get max joint values.

Returns
Maximal joint values for the 6 dof X,Y,Z,A,B,C. Translation X,Y,Z are expressed in meters. Rotation A,B,C in radians.

Definition at line 1020 of file vpAfma6.cpp.

References vpAfma6::_joint_max.

vpColVector vpAfma6::getJointMin ( ) const
inherited

Get min joint values.

Returns
Minimal joint values for the 6 dof X,Y,Z,A,B,C. Translation X,Y,Z are expressed in meters. Rotation A,B,C in radians.

Definition at line 1003 of file vpAfma6.cpp.

References vpAfma6::_joint_min.

double vpAfma6::getLong56 ( ) const
inherited

Return the distance between join 5 and 6.

Returns
Distance between join 5 and 6.

Definition at line 1047 of file vpAfma6.cpp.

References vpAfma6::_long_56.

double vpRobot::getMaxTranslationVelocity ( void  ) const
inherited
vpColVector vpRobot::getPosition ( const vpRobot::vpControlFrameType  frame)
inherited

Return the current robot position in the specified frame.

Definition at line 218 of file vpRobot.cpp.

void vpSimulatorAfma6::getPosition ( const vpRobot::vpControlFrameType  frame,
vpColVector q 
)
virtual

Get the current position of the robot.

Parameters
frame: Control frame type in which to get the position, either :
  • in the camera cartesien frame,
  • joint (articular) coordinates of each axes
  • in a reference or fixed cartesien frame attached to the robot base
  • in a mixt cartesien frame (translation in reference frame, and rotation in camera frame)
q: Measured position of the robot:
  • in camera cartesien frame, a 6 dimension vector, set to 0.
  • in articular, a 6 dimension vector corresponding to the joint position of each dof in radians.
  • in reference frame, a 6 dimension vector, the first 3 values correspond to the translation tx, ty, tz in meters (like a vpTranslationVector), and the last 3 values to the rx, ry, rz rotation (like a vpRxyzVector). The code below show how to convert this position into a vpHomogeneousMatrix:
#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
#include <visp3/core/vpTranslationVector.h>
#include <visp3/core/vpRxyzVector.h>
#include <visp3/core/vpRotationMatrix.h>
#include <visp3/core/vpHomogeneousMatrix.h>
int main()
{
vpColVector position;
vpTranslationVector ftc; // reference frame to camera frame translations
vpRxyzVector frc; // reference frame to camera frame rotations
// Update the transformation between reference frame and camera frame
for (int i=0; i < 3; i++) {
ftc[i] = position[i]; // tx, ty, tz
frc[i] = position[i+3]; // ry, ry, rz
}
// Create a rotation matrix from the Rxyz rotation angles
vpRotationMatrix fRc(frc); // reference frame to camera frame rotation matrix
// Create the camera to fix frame transformation in terms of a
// homogeneous matrix
}
See Also
getPosition(const vpRobot::vpControlFrameType frame, vpColVector &q, double &timestamp)
setPosition(const vpRobot::vpControlFrameType frame, const vpColVector & r)

Implements vpRobot.

Definition at line 1703 of file vpSimulatorAfma6.cpp.

References vpRobot::ARTICULAR_FRAME, vpRobot::CAMERA_FRAME, vpHomogeneousMatrix::extract(), vpRobotWireFrameSimulator::get_artCoord(), vpAfma6::get_fMc(), vpRobotException::lowLevelError, vpRobot::MIXT_FRAME, vpRobot::REFERENCE_FRAME, vpColVector::resize(), and vpERROR_TRACE.

Referenced by getPosition().

void vpSimulatorAfma6::getPosition ( const vpRobot::vpControlFrameType  frame,
vpColVector q,
double &  timestamp 
)

Get the current time stamped position of the robot.

Parameters
frame: Control frame type in which to get the position, either :
  • in the camera cartesien frame,
  • joint (articular) coordinates of each axes
  • in a reference or fixed cartesien frame attached to the robot base
  • in a mixt cartesien frame (translation in reference frame, and rotation in camera frame)
q: Measured position of the robot:
  • in camera cartesien frame, a 6 dimension vector, set to 0.
  • in articular, a 6 dimension vector corresponding to the joint position of each dof in radians.
  • in reference frame, a 6 dimension vector, the first 3 values correspond to the translation tx, ty, tz in meters (like a vpTranslationVector), and the last 3 values to the rx, ry, rz rotation (like a vpRxyzVector). The code below show how to convert this position into a vpHomogeneousMatrix:
timestamp: Unix time in second since January 1st 1970.
See Also
getPosition(const vpRobot::vpControlFrameType frame, vpColVector &q)

Definition at line 1778 of file vpSimulatorAfma6.cpp.

References getPosition(), and vpTime::measureTimeSecond().

void vpSimulatorAfma6::getPosition ( const vpRobot::vpControlFrameType  frame,
vpPoseVector position 
)

Get the current position of the robot.

Similar as getPosition(const vpRobot::vpControlFrameType frame, vpColVector &)

The difference is here that the position is returned using a ThetaU representation.

See Also
getPosition(const vpRobot::vpControlFrameType frame, vpColVector &)

Definition at line 1796 of file vpSimulatorAfma6.cpp.

References getPosition().

void vpSimulatorAfma6::getPosition ( const vpRobot::vpControlFrameType  frame,
vpPoseVector position,
double &  timestamp 
)

Get the current time stamped position of the robot.

Similar as getPosition(const vpRobot::vpControlFrameType frame, vpColVector &, double &)

The difference is here that the position is returned using a ThetaU representation.

Definition at line 1824 of file vpSimulatorAfma6.cpp.

References getPosition(), and vpTime::measureTimeSecond().

double vpSimulatorAfma6::getPositioningVelocity ( void  )
inline

Definition at line 210 of file vpSimulatorAfma6.h.

Referenced by findHighestPositioningSpeed().

vpControlFrameType vpRobot::getRobotFrame ( void  ) const
inlineprotectedinherited
vpAfma6ToolType vpAfma6::getToolType ( ) const
inlineinherited

Get the current tool type.

Definition at line 158 of file vpAfma6.h.

Referenced by vpAfma6::getCameraParameters(), getCameraParameters(), and initArms().

void vpSimulatorAfma6::getVelocity ( const vpRobot::vpControlFrameType  frame,
vpColVector vel 
)

Get the robot velocities.

Parameters
frame: Frame in wich velocities are mesured.
vel: Measured velocities. Translations are expressed in m/s and rotations in rad/s.
Warning
In camera frame, reference frame and mixt frame, the representation of the rotation is ThetaU. In that cases, $velocity = [\dot x, \dot y, \dot z, \dot {\theta U}_x, \dot {\theta U}_y, \dot {\theta U}_z]$.
#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
int main()
{
// Set requested joint velocities
vpColVector q_dot(6);
q_dot[0] = 0.1; // Joint 1 velocity in m/s
q_dot[1] = 0.2; // Joint 2 velocity in m/s
q_dot[2] = 0.3; // Joint 3 velocity in m/s
q_dot[3] = M_PI/8; // Joint 4 velocity in rad/s
q_dot[4] = M_PI/4; // Joint 5 velocity in rad/s
q_dot[5] = M_PI/16;// Joint 6 velocity in rad/s
// Moves the joint in velocity
// Initialisation of the velocity measurement
vpColVector q_dot_mes; // Measured velocities
for ( ; ; ) {
vpTime::wait(40); // wait 40 ms
// here q_dot_mes is equal to [0.1, 0.2, 0.3, M_PI/8, M_PI/4, M_PI/16]
}
}

Definition at line 1133 of file vpSimulatorAfma6.cpp.

References vpAfma6::_eMc, vpRobot::ARTICULAR_FRAME, vpRobot::CAMERA_FRAME, vpRobotWireFrameSimulator::get_artCoord(), vpRobotWireFrameSimulator::get_artVel(), vpAfma6::get_eJe(), vpAfma6::get_fJe(), vpRobot::MIXT_FRAME, vpRobot::REFERENCE_FRAME, vpColVector::resize(), and vpERROR_TRACE.

Referenced by getVelocity().

void vpSimulatorAfma6::getVelocity ( const vpRobot::vpControlFrameType  frame,
vpColVector vel,
double &  timestamp 
)

Get the robot time stamped velocities.

Parameters
frame: Frame in wich velocities are mesured.
vel: Measured velocities. Translations are expressed in m/s and rotations in rad/s.
timestamp: Unix time in second since January 1st 1970.
Warning
In camera frame, reference frame and mixt frame, the representation of the rotation is ThetaU. In that cases, $velocity = [\dot x, \dot y, \dot z, \dot {\theta U}_x, \dot {\theta U}_y, \dot {\theta U}_z]$.
See Also
getVelocity(const vpRobot::vpControlFrameType frame, vpColVector & vel)

Definition at line 1192 of file vpSimulatorAfma6.cpp.

References getVelocity(), and vpTime::measureTimeSecond().

vpColVector vpSimulatorAfma6::getVelocity ( const vpRobot::vpControlFrameType  frame)

Get the robot velocities.

Parameters
frame: Frame in wich velocities are mesured.
Returns
Measured velocities. Translations are expressed in m/s and rotations in rad/s.
#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
int main()
{
// Set requested joint velocities
vpColVector q_dot(6);
q_dot[0] = 0.1; // Joint 1 velocity in rad/s
q_dot[1] = 0.2; // Joint 2 velocity in rad/s
q_dot[2] = 0.3; // Joint 3 velocity in rad/s
q_dot[3] = M_PI/8; // Joint 4 velocity in rad/s
q_dot[4] = M_PI/4; // Joint 5 velocity in rad/s
q_dot[5] = M_PI/16;// Joint 6 velocity in rad/s
// Moves the joint in velocity
// Initialisation of the velocity measurement
vpColVector q_dot_mes; // Measured velocities
for ( ; ; ) {
vpTime::wait(40); // wait 40 ms
// here q_dot_mes is equal to [0.1, 0.2, 0.3, M_PI/8, M_PI/4, M_PI/16]
}
}

Definition at line 1241 of file vpSimulatorAfma6.cpp.

References getVelocity().

vpColVector vpSimulatorAfma6::getVelocity ( const vpRobot::vpControlFrameType  frame,
double &  timestamp 
)

Get the time stamped robot velocities.

Parameters
frame: Frame in wich velocities are mesured.
timestamp: Unix time in second since January 1st 1970.
Returns
Measured velocities. Translations are expressed in m/s and rotations in rad/s.
See Also
getVelocity(vpRobot::vpControlFrameType frame)

Definition at line 1262 of file vpSimulatorAfma6.cpp.

References getVelocity(), and vpTime::measureTimeSecond().

void vpAfma6::init ( const std::string &  camera_extrinsic_parameters)
inherited

Read files containing the constant parameters related to the robot tools in order to set the end-effector to tool transformation.

Parameters
camera_extrinsic_parameters: Filename containing the camera extrinsic parameters.

Definition at line 228 of file vpAfma6.cpp.

References vpAfma6::parseConfigFile().

void vpAfma6::init ( const std::string &  camera_extrinsic_parameters,
const std::string &  camera_intrinsic_parameters 
)
inherited

Read files containing the constant parameters related to the robot kinematics and to the end-effector to camera transformation.

Parameters
camera_extrinsic_parameters: Filename containing the constant parameters of the robot kinematics $^e{\bf M}_c $ transformation.
camera_intrinsic_parameters: Filename containing the camera extrinsic parameters.

Definition at line 174 of file vpAfma6.cpp.

References vpAfma6::parseConfigFile().

void vpAfma6::init ( vpAfma6::vpAfma6ToolType  tool,
const std::string &  filename 
)
inherited

Set the type of tool attached to the robot and transformation between the end-effector and the tool ( $^e{\bf M}c$). This last parameter is loaded from a file.

Parameters
tool: Type of tool in use.
filename: Path of the configuration file containing the transformation between the end-effector frame and the tool frame.

The configuration file should have the form below:

# Start with any number of consecutive lines
# beginning with the symbol '#'
#
# The 3 following lines contain the name of the camera,
# the rotation parameters of the geometric transformation
# using the Euler angles in degrees with convention XYZ and
# the translation parameters expressed in meters
CAMERA CameraName
eMc_ROT_XYZ 10.0 -90.0 20.0
eMc_TRANS_XYZ 0.05 0.01 0.06
See Also
init(vpAfma6::vpToolType, vpCameraParameters::vpCameraParametersProjType), init(vpAfma6::vpToolType, const vpHomogeneousMatrix&)

Definition at line 212 of file vpAfma6.cpp.

References vpAfma6::parseConfigFile(), and vpAfma6::setToolType().

void vpAfma6::init ( vpAfma6::vpAfma6ToolType  tool,
const vpHomogeneousMatrix eMc 
)
inherited

Set the type of tool attached to the robot and the transformation between the end-effector and the tool ( $^e{\bf M}c$).

Parameters
tool: Type of tool in use.
eMc: Homogeneous matrix representation of the transformation between the end-effector frame and the tool frame.
See Also
init(vpAfma6::vpAfma6ToolType, vpCameraParameters::vpCameraParametersProjType), init(vpAfma6::vpAfma6ToolType, const std::string&)

Definition at line 248 of file vpAfma6.cpp.

References vpAfma6::set_eMc(), and vpAfma6::setToolType().

Initialize the robot kinematics with the extrinsic calibration parameters associated to a specific camera.

The eMc parameters depend on the camera.

Warning
Only perspective projection without distortion is available!
Parameters
tool: Tool to use. Note that the generic camera is not handled.
proj_model: Projection model associated to the camera.
See Also
vpCameraParameters, init()

Definition at line 316 of file vpSimulatorAfma6.cpp.

References vpAfma6::_eMc, vpAfma6::_erc, vpAfma6::_etc, vpHomogeneousMatrix::buildFrom(), vpException::dimensionError, vpRobotWireFrameSimulator::get_displayBusy(), vpAfma6::projModel, vpMath::rad(), vpRobotWireFrameSimulator::robotArms, vpRobotWireFrameSimulator::set_displayBusy(), setCameraParameters(), vpAfma6::setToolType(), vpAfma6::TOOL_CCMOP, vpAfma6::TOOL_CUSTOM, vpAfma6::TOOL_GENERIC_CAMERA, vpAfma6::TOOL_GRIPPER, vpAfma6::TOOL_VACUUM, and vpTime::wait().

void vpSimulatorAfma6::init ( void  )
protectedvirtual

Method which initialises the parameters linked to the robot caracteristics.

Set the path to the arm files (*.bnd and *.sln) used by the simulator. If the path set in vpConfig.h in VISP_ROBOT_ARMS_DIR macro is not valid, the path is set from the VISP_ROBOT_ARMS_DIR environment variable that the user has to set.

Reimplemented from vpRobotWireFrameSimulator.

Definition at line 215 of file vpSimulatorAfma6.cpp.

References vpAfma6::_joint_max, vpAfma6::_joint_min, vpRobotWireFrameSimulator::artCoord, vpRobot::ARTICULAR_FRAME, vpRobotWireFrameSimulator::artVel, vpIoTools::checkDirectory(), defaultPositioningVelocity, vpRobotWireFrameSimulator::fMi, vpIoTools::getenv(), vpAfma6::njoint, vpColVector::resize(), vpRobot::setRobotFrame(), setRobotState(), vpRobotWireFrameSimulator::size_fMi, vpIoTools::splitChain(), vpRobot::STATE_STOP, and vpAfma6::TOOL_CCMOP.

Referenced by vpSimulatorAfma6().

void vpSimulatorAfma6::initArms ( )
protectedvirtual

Initialise the display of the robot's arms.

Set the path to the scene files (*.bnd and *.sln) used by the simulator. If the path set in vpConfig.h in VISP_SCENES_DIR macro is not valid, the path is set from the VISP_SCENES_DIR environment variable that the user has to set.

Implements vpRobotWireFrameSimulator.

Definition at line 2326 of file vpSimulatorAfma6.cpp.

References vpWireFrameSimulator::camera, vpWireFrameSimulator::cameraFactor, vpIoTools::checkDirectory(), vpException::dimensionError, vpWireFrameSimulator::displayCamera, vpIoTools::getenv(), vpAfma6::getToolType(), vpRobotWireFrameSimulator::robotArms, vpIoTools::splitChain(), vpAfma6::TOOL_CCMOP, vpAfma6::TOOL_CUSTOM, vpAfma6::TOOL_GENERIC_CAMERA, vpAfma6::TOOL_GRIPPER, and vpAfma6::TOOL_VACUUM.

Referenced by initDisplay().

bool vpSimulatorAfma6::initialiseCameraRelativeToObject ( const vpHomogeneousMatrix cMo_)

This method enables to initialise the joint coordinates of the robot in order to position the camera relative to the object.

Before using this method it is advised to set the position of the object thanks to the set_fMo() method.

In other terms, set the world to camera transformation ${^f}{\bf M}_c = {^f}{\bf M}_o \; ({^c}{\bf M}_o)^{-1}$, and from the inverse kinematics set the joint positions ${\bf q}$ that corresponds to the ${^f}{\bf M}_c$ transformation.

Parameters
cMo_: the desired pose of the camera.
Returns
false if the robot kinematics is not able to reach the cMo position.

Definition at line 2527 of file vpSimulatorAfma6.cpp.

References compute_fMi(), vpWireFrameSimulator::fMo, vpRobotWireFrameSimulator::get_artCoord(), vpAfma6::getInverseKinematics(), vpHomogeneousMatrix::inverse(), vpRobotWireFrameSimulator::set_artCoord(), vpRobotWireFrameSimulator::set_artVel(), vpRobotWireFrameSimulator::set_velocity(), vpColVector::t(), vpRobotWireFrameSimulator::verbose_, and vpERROR_TRACE.

void vpSimulatorAfma6::initialiseObjectRelativeToCamera ( const vpHomogeneousMatrix cMo_)

This method enables to initialise the pose between the object and the reference frame, in order to position the object relative to the camera.

Before using this method it is advised to set the articular coordinates of the robot.

In other terms, set the world to object transformation ${^f}{\bf M}_o = {^f}{\bf M}_c \; {^c}{\bf M}_o$ where $ {^f}{\bf M}_c = f({\bf q})$ with ${\bf q}$ the robot joint position

Parameters
cMo_: the desired pose of the camera.

Definition at line 2568 of file vpSimulatorAfma6.cpp.

References vpWireFrameSimulator::fMo, get_fMi(), vpRobotWireFrameSimulator::set_artVel(), and vpRobotWireFrameSimulator::set_velocity().

void vpRobotWireFrameSimulator::initScene ( const vpSceneObject obj,
const vpSceneDesiredObject desired_object 
)
inherited

Initialize the display. It enables to choose the type of scene which will be used to display the object at the current position and at the desired position.

It exists several default scenes you can use. Use the vpSceneObject and the vpSceneDesiredObject attributes to use them in this method. The corresponding files are stored in the "data" folder which is in the ViSP build directory.

Parameters
obj: Type of scene used to display the object at the current position.
desired_object: Type of scene used to display the object at the desired pose (in the internal view).

Definition at line 132 of file vpRobotWireFrameSimulator.cpp.

References vpWireFrameSimulator::camera, vpWireFrameSimulator::displayCamera, and vpWireFrameSimulator::initScene().

void vpRobotWireFrameSimulator::initScene ( const char *  obj,
const char *  desired_object 
)
inherited

Initialize the display. It enables to choose the type of scene which will be used to display the object at the current position and at the desired position.

Here you can use the scene you want. You have to set the path to the .bnd file which is a scene file. It is also possible to use a vrml (.wrl) file.

Parameters
obj: Path to the scene file you want to use.
desired_object: Path to the scene file you want to use.

Definition at line 155 of file vpRobotWireFrameSimulator.cpp.

References vpWireFrameSimulator::camera, vpWireFrameSimulator::displayCamera, and vpWireFrameSimulator::initScene().

void vpRobotWireFrameSimulator::initScene ( const vpSceneObject obj)
inherited

Initialize the display. It enables to choose the type of object which will be used to display the object at the current position. The object at the desired position is not displayed.

It exists several default scenes you can use. Use the vpSceneObject attributes to use them in this method. The corresponding files are stored in the "data" folder which is in the ViSP build directory.

Parameters
obj: Type of scene used to display the object at the current position.

Definition at line 176 of file vpRobotWireFrameSimulator.cpp.

References vpWireFrameSimulator::camera, vpWireFrameSimulator::displayCamera, and vpWireFrameSimulator::initScene().

void vpRobotWireFrameSimulator::initScene ( const char *  obj)
inherited

Initialize the display. It enables to choose the type of scene which will be used to display the object at the current position. The object at the desired position is not displayed.

Here you can use the scene you want. You have to set the path to the .bnd file which is a scene file, or the vrml file.

Parameters
obj: Path to the scene file you want to use.

Definition at line 197 of file vpRobotWireFrameSimulator.cpp.

References vpWireFrameSimulator::camera, vpWireFrameSimulator::displayCamera, and vpWireFrameSimulator::initScene().

void vpWireFrameSimulator::initScene ( const vpSceneObject obj,
const vpSceneDesiredObject desired_object,
const std::list< vpImageSimulator > &  imObj 
)
inherited

Initialize the simulator. It enables to choose the type of scene which will be used to display the object at the current position and at the desired position.

It exists several default scenes you can use. Use the vpSceneObject and the vpSceneDesiredObject attributes to use them in this method. The corresponding files are stored in the "data" folder which is in the ViSP build directory.

It is also possible to add a list of vpImageSimulator instances. They will be automatically projected into the image. The position of the four corners have to be given in the object frame.

Parameters
obj: Type of scene used to display the object at the current position.
desired_object: Type of scene used to display the object at the desired pose (in the internal view).
imObj: A list of vpImageSimulator instances.

Definition at line 371 of file vpWireFrameSimulator.cpp.

References vpWireFrameSimulator::displayImageSimulator, vpWireFrameSimulator::initScene(), and vpWireFrameSimulator::objectImage.

void vpWireFrameSimulator::initScene ( const char *  obj,
const char *  desired_object,
const std::list< vpImageSimulator > &  imObj 
)
inherited

Initialize the simulator. It enables to choose the type of scene which will be used to display the object at the current position and at the desired position.

Here you can use the scene you want. You have to set the path to a .bnd or a .wrl file which is a 3D model file.

It is also possible to add a list of vpImageSimulator instances. They will be automatically projected into the image. The position of the four corners have to be given in the object frame.

Parameters
obj: Path to the scene file you want to use.
desired_object: Path to the scene file you want to use.
imObj: A list of vpImageSimulator instances.

Definition at line 465 of file vpWireFrameSimulator.cpp.

References vpWireFrameSimulator::displayImageSimulator, vpWireFrameSimulator::initScene(), and vpWireFrameSimulator::objectImage.

void vpWireFrameSimulator::initScene ( const vpSceneObject obj,
const std::list< vpImageSimulator > &  imObj 
)
inherited

Initialize the simulator. It enables to choose the type of object which will be used to display the object at the current position. The object at the desired position is not displayed.

It exists several default scenes you can use. Use the vpSceneObject attributes to use them in this method. The corresponding files are stored in the "data" folder which is in the ViSP build directory.

It is also possible to add a list of vpImageSimulator instances. They will be automatically projected into the image. The position of the four corners have to be given in the object frame.

Parameters
obj: Type of scene used to display the object at the current position.
imObj: A list of vpImageSimulator instances.

Definition at line 548 of file vpWireFrameSimulator.cpp.

References vpWireFrameSimulator::displayImageSimulator, vpWireFrameSimulator::initScene(), and vpWireFrameSimulator::objectImage.

void vpWireFrameSimulator::initScene ( const char *  obj,
const std::list< vpImageSimulator > &  imObj 
)
inherited

Initialize the simulator. It enables to choose the type of scene which will be used to display the object at the current position. The object at the desired position is not displayed.

Here you can use the scene you want. You have to set the path to a .bnd or a .wrl file which is a 3D model file.

It is also possible to add a list of vpImageSimulator instances. They will be automatically projected into the image. The position of the four corners have to be given in the object frame.

Parameters
obj: Path to the scene file you want to use.
imObj: A list of vpImageSimulator instances.

Definition at line 621 of file vpWireFrameSimulator.cpp.

References vpWireFrameSimulator::displayImageSimulator, vpWireFrameSimulator::initScene(), and vpWireFrameSimulator::objectImage.

int vpSimulatorAfma6::isInJointLimit ( void  )
protectedvirtual

Method used to check if the robot reached a joint limit.

Implements vpRobotWireFrameSimulator.

Definition at line 1894 of file vpSimulatorAfma6.cpp.

References vpAfma6::_joint_max, vpAfma6::_joint_min, and vpRobotWireFrameSimulator::get_artCoord().

Referenced by updateArticularPosition().

static void* vpRobotWireFrameSimulator::launcher ( void *  arg)
inlinestaticprotectedinherited

Function used to launch the thread which moves the robot.

Definition at line 365 of file vpRobotWireFrameSimulator.h.

Referenced by vpSimulatorAfma6(), and vpSimulatorViper850::vpSimulatorViper850().

void vpSimulatorAfma6::move ( const char *  filename)

Moves the robot to the joint position specified in the filename.

Parameters
filenameFile containing a joint position.
See Also
readPosFile

Definition at line 2199 of file vpSimulatorAfma6.cpp.

References vpRobot::ARTICULAR_FRAME, readPosFile(), setPosition(), setRobotState(), and vpRobot::STATE_POSITION_CONTROL.

void vpAfma6::parseConfigFile ( const std::string &  filename)
inherited

This function gets the robot constant parameters from a file.

Parameters
filename: File name containing the robot constant parameters, like max/min joint values, distance between 5 and 6 axis, coupling factor between axis 5 and 6, and the hand-to-eye homogeneous matrix.

Definition at line 1063 of file vpAfma6.cpp.

References vpAfma6::_coupl_56, vpAfma6::_eMc, vpAfma6::_erc, vpAfma6::_etc, vpAfma6::_joint_max, vpAfma6::_joint_min, vpAfma6::_long_56, vpHomogeneousMatrix::buildFrom(), and vpRobotException::readingParametersError.

Referenced by vpAfma6::init().

vpImagePoint vpWireFrameSimulator::projectCameraTrajectory ( const vpImage< unsigned char > &  I,
const vpHomogeneousMatrix cMo_,
const vpHomogeneousMatrix fMo_ 
)
protectedinherited
vpImagePoint vpWireFrameSimulator::projectCameraTrajectory ( const vpImage< vpRGBa > &  I,
const vpHomogeneousMatrix cMo_,
const vpHomogeneousMatrix fMo_,
const vpHomogeneousMatrix cMf 
)
protectedinherited
vpImagePoint vpWireFrameSimulator::projectCameraTrajectory ( const vpImage< unsigned char > &  I,
const vpHomogeneousMatrix cMo_,
const vpHomogeneousMatrix fMo_,
const vpHomogeneousMatrix cMf 
)
protectedinherited
bool vpSimulatorAfma6::readPosFile ( const std::string &  filename,
vpColVector q 
)
static

Read joint positions in a specific Afma6 position file.

This position file has to start with a header. The six joint positions are given after the "R:" keyword. The first 3 values correspond to the joint translations X,Y,Z expressed in meters. The 3 last values correspond to the joint rotations A,B,C expressed in degres to be more representative for the user. Theses values are then converted in radians in q. The character "#" starting a line indicates a comment.

A typical content of such a file is given below:

#AFMA6 - Position - Version 2.01
# file: "myposition.pos "
#
# R: X Y Z A B C
# Joint position: X, Y, Z: translations in meters
# A, B, C: rotations in degrees
#
R: 0.1 0.3 -0.25 -80.5 80 0
Parameters
filename: Name of the position file to read.
q: Joint positions: X,Y,Z,A,B,C. Translations X,Y,Z are expressed in meters, while joint rotations A,B,C in radians.
Returns
true if the positions were successfully readen in the file. false, if an error occurs.

The code below shows how to read a position from a file and move the robot to this position.

vpColVector q; // Joint position
robot.readPosFile("myposition.pos", q); // Set the joint position from the file
robot.setPositioningVelocity(5); // Positioning velocity set to 5%
robot.setPosition(vpRobot::ARTICULAR_FRAME, q); // Move to the joint position
See Also
savePosFile()

Definition at line 2079 of file vpSimulatorAfma6.cpp.

References vpAfma6::njoint, vpMath::rad(), vpColVector::resize(), and vpIoTools::splitChain().

Referenced by move(), and setPosition().

vpColVector vpRobot::saturateVelocities ( const vpColVector v_in,
const vpColVector v_max,
bool  verbose = false 
)
staticinherited

Saturate velocities.

Parameters
v_in: Vector of input velocities to saturate. Translation velocities should be expressed in m/s while rotation velocities in rad/s.
v_max: Vector of maximal allowed velocities. Maximal translation velocities should be expressed in m/s while maximal rotation velocities in rad/s.
verbose: Print a message indicating which axis causes the saturation.
Returns
Saturated velocities.
Exceptions
vpRobotException::dimensionError: If the input vectors have different dimensions.

The code below shows how to use this static method in order to saturate a velocity skew vector.

#include <iostream>
#include <visp3/robot/vpRobot.h>
int main()
{
// Set a velocity skew vector
v[0] = 0.1; // vx in m/s
v[1] = 0.2; // vy
v[2] = 0.3; // vz
v[3] = vpMath::rad(10); // wx in rad/s
v[4] = vpMath::rad(-10); // wy
v[5] = vpMath::rad(20); // wz
// Set the maximal allowed velocities
vpColVector v_max(6);
for (int i=0; i<3; i++)
v_max[i] = 0.3; // in translation (m/s)
for (int i=3; i<6; i++)
v_max[i] = vpMath::rad(10); // in rotation (rad/s)
// Compute the saturated velocity skew vector
vpColVector v_sat = vpRobot::saturateVelocities(v, v_max, true);
std::cout << "v : " << v.t() << std::endl;
std::cout << "v max: " << v_max.t() << std::endl;
std::cout << "v sat: " << v_sat.t() << std::endl;
return 0;
}

Definition at line 163 of file vpRobot.cpp.

References vpException::dimensionError, and vpArray2D< Type >::size().

Referenced by vpSimulatorCamera::setVelocity(), vpSimulatorPioneer::setVelocity(), vpRobotCamera::setVelocity(), vpSimulatorPioneerPan::setVelocity(), vpRobotPioneer::setVelocity(), vpRobotAfma4::setVelocity(), vpRobotAfma6::setVelocity(), vpRobotViper650::setVelocity(), and vpRobotViper850::setVelocity().

bool vpSimulatorAfma6::savePosFile ( const std::string &  filename,
const vpColVector q 
)
static

Save joint (articular) positions in a specific Afma6 position file.

This position file starts with a header on the first line. After convertion of the rotations in degrees, the joint position q is written on a line starting with the keyword "R: ". See readPosFile() documentation for an example of such a file.

Parameters
filename: Name of the position file to create.
q: Joint positions [X,Y,Z,A,B,C] to save in the filename. Translations X,Y,Z are expressed in meters, while rotations A,B,C in radians.
Warning
The joint rotations A,B,C written in the file are converted in degrees to be more representative for the user.
Returns
true if the positions were successfully saved in the file. false, if an error occurs.
See Also
readPosFile()

Definition at line 2162 of file vpSimulatorAfma6.cpp.

References vpMath::deg().

void vpRobotWireFrameSimulator::set_displayBusy ( const bool &  status)
inlineprotectedinherited
void vpAfma6::set_eMc ( const vpHomogeneousMatrix eMc)
virtualinherited

Set the geometric transformation between the end-effector frame and the tool frame (commonly a camera).

Parameters
eMc: Transformation between the end-effector frame and the tool frame.

Reimplemented in vpRobotAfma6.

Definition at line 1164 of file vpAfma6.cpp.

References vpAfma6::_eMc, vpAfma6::_erc, vpAfma6::_etc, vpRxyzVector::buildFrom(), and vpHomogeneousMatrix::getTranslationVector().

Referenced by vpAfma6::init(), and vpRobotAfma6::set_eMc().

void vpRobotWireFrameSimulator::set_fMo ( const vpHomogeneousMatrix fMo_)
inlineinherited

Set the pose between the object and the fixed world frame.

Parameters
fMo_: The pose between the object and the fixed world frame.

Definition at line 349 of file vpRobotWireFrameSimulator.h.

void vpRobotWireFrameSimulator::setCameraColor ( const vpColor  col)
inlineinherited

Set the color used to display the camera in the external view.

Parameters
col: The desired color.

Definition at line 255 of file vpRobotWireFrameSimulator.h.

void vpWireFrameSimulator::setCameraColor ( const vpColor col)
inlineinherited

Set the color used to display the camera in the external view.

Parameters
col: The desired color.
Examples:
wireframeSimulator.cpp.

Definition at line 409 of file vpWireFrameSimulator.h.

void vpSimulatorAfma6::setCameraParameters ( const vpCameraParameters cam)

Set the intrinsic camera parameters.

Parameters
cam: The desired camera parameters.

Definition at line 509 of file vpSimulatorAfma6.cpp.

References vpCameraParameters::get_px(), vpCameraParameters::get_py(), vpWireFrameSimulator::px_int, and vpWireFrameSimulator::py_int.

Referenced by init().

void vpWireFrameSimulator::setCameraPositionRelObj ( const vpHomogeneousMatrix cMo_)
inlineinherited

Set the position of the camera relative to the object.

Parameters
cMo_: The pose of the camera.
Examples:
servoSimu4Points.cpp, servoSimuCylinder.cpp, servoSimuSphere.cpp, tutorial-ibvs-4pts-wireframe-camera.cpp, and wireframeSimulator.cpp.

Definition at line 415 of file vpWireFrameSimulator.h.

References vpHomogeneousMatrix::inverse().

void vpWireFrameSimulator::setCameraPositionRelWorld ( const vpHomogeneousMatrix fMc_)
inlineinherited

Set the position of the the world reference frame relative to the camera.

Parameters
fMc_: The pose of the camera.

Definition at line 422 of file vpWireFrameSimulator.h.

References vpHomogeneousMatrix::inverse().

void vpWireFrameSimulator::setCameraSizeFactor ( const float  factor)
inlineinherited

Set the parameter which enables to choose the size of the main camera in the external camera views. By default this parameter is set to 1.

Parameters
factor: The ration for the camera size.

Definition at line 429 of file vpWireFrameSimulator.h.

void vpWireFrameSimulator::setCameraTrajectoryColor ( const vpColor col)
inlineinherited

Set the color used to display the camera trajectory in the external view.

Parameters
col: The desired color.

Definition at line 436 of file vpWireFrameSimulator.h.

void vpWireFrameSimulator::setCameraTrajectoryDisplayType ( const vpCameraTrajectoryDisplayType camTraj_type)
inlineinherited

Set the way to display the history of the main camera trajectory in the main external view. The choice is given between displaying lines and points.

Parameters
camTraj_type: The chosen way to display the camera trajectory.

Definition at line 443 of file vpWireFrameSimulator.h.

void vpRobotWireFrameSimulator::setConstantSamplingTimeMode ( const bool  _constantSamplingTimeMode)
inlineinherited

Set the flag used to force the sampling time in the thread computing the robot's displacement to a constant value; see setSamplingTime(). It may be useful if the main thread (computing the features) is very time consuming. False by default.

Parameters
_constantSamplingTimeMode: The new value of the constantSamplingTimeMode flag.

Definition at line 265 of file vpRobotWireFrameSimulator.h.

void vpRobotWireFrameSimulator::setCurrentViewColor ( const vpColor  col)
inlineinherited

Set the color used to display the object at the current position in the robot's camera view.

Parameters
col: The desired color.

Definition at line 274 of file vpRobotWireFrameSimulator.h.

void vpWireFrameSimulator::setCurrentViewColor ( const vpColor col)
inlineinherited

Set the color used to display the object at the current position.

Parameters
col: The desired color.
Examples:
wireframeSimulator.cpp.

Definition at line 450 of file vpWireFrameSimulator.h.

void vpRobotWireFrameSimulator::setDesiredCameraPosition ( const vpHomogeneousMatrix  cdMo_)
inlineinherited

Set the desired position of the robot's camera relative to the object.

Parameters
cdMo_: The desired pose of the camera.

Definition at line 288 of file vpRobotWireFrameSimulator.h.

References vpWireFrameSimulator::setDesiredCameraPosition().

void vpWireFrameSimulator::setDesiredCameraPosition ( const vpHomogeneousMatrix cdMo_)
inlineinherited

Set the desired position of the camera relative to the object.

Parameters
cdMo_: The desired pose of the camera.
Examples:
servoSimu4Points.cpp, servoSimuCylinder.cpp, servoSimuSphere.cpp, tutorial-ibvs-4pts-wireframe-camera.cpp, and wireframeSimulator.cpp.

Definition at line 456 of file vpWireFrameSimulator.h.

Referenced by vpRobotWireFrameSimulator::setDesiredCameraPosition().

void vpRobotWireFrameSimulator::setDesiredViewColor ( const vpColor  col)
inlineinherited

Set the color used to display the object at the desired position in the robot's camera view.

Parameters
col: The desired color.

Definition at line 281 of file vpRobotWireFrameSimulator.h.

void vpWireFrameSimulator::setDesiredViewColor ( const vpColor col)
inlineinherited

Set the color used to display the object at the desired position.

Parameters
col: The desired color.
Examples:
wireframeSimulator.cpp.

Definition at line 462 of file vpWireFrameSimulator.h.

void vpWireFrameSimulator::setDisplayCameraTrajectory ( const bool &  do_display)
inlineinherited

Enable or disable the displaying of the camera trajectory in the main external camera view.

By default the trajectory is displayed.

Parameters
do_display: Set to true to display the camera trajectory.

Definition at line 470 of file vpWireFrameSimulator.h.

void vpRobotWireFrameSimulator::setDisplayRobotType ( const vpDisplayRobotType  dispType)
inlineinherited

Set the way to draw the robot. Depending on what you choose you can display a 3D wireframe model or a set of lines linking the frames used to compute the geometrical model.

Parameters
dispType: Type of display. Can be MODEL_3D or MODEL_DH.

Definition at line 298 of file vpRobotWireFrameSimulator.h.

void vpWireFrameSimulator::setExternalCameraParameters ( const vpCameraParameters cam)
inlineinherited

Set the internal camera parameters.

Parameters
cam: The desired camera parameters.
Examples:
servoSimu4Points.cpp, servoSimuCylinder.cpp, servoSimuSphere.cpp, tutorial-ibvs-4pts-wireframe-camera.cpp, and wireframeSimulator.cpp.

Definition at line 477 of file vpWireFrameSimulator.h.

References vpCameraParameters::get_px(), and vpCameraParameters::get_py().

Referenced by initDisplay(), and vpSimulatorViper850::initDisplay().

void vpRobotWireFrameSimulator::setExternalCameraPosition ( const vpHomogeneousMatrix  camMf_)
inlineinherited

Set the external camera point of view.

Parameters
camMf_: The pose of the external camera relative to the world reference frame.

Definition at line 304 of file vpRobotWireFrameSimulator.h.

References vpWireFrameSimulator::setExternalCameraPosition().

Referenced by initDisplay(), and vpSimulatorViper850::initDisplay().

void vpWireFrameSimulator::setExternalCameraPosition ( const vpHomogeneousMatrix cam_Mf)
inlineinherited

Set the external camera point of view.

Parameters
cam_Mf: The pose of the external camera relative to the world reference frame.
Examples:
servoSimu4Points.cpp, servoSimuCylinder.cpp, servoSimuSphere.cpp, tutorial-ibvs-4pts-wireframe-camera.cpp, and wireframeSimulator.cpp.

Definition at line 486 of file vpWireFrameSimulator.h.

References vpTranslationVector::buildFrom().

Referenced by vpRobotWireFrameSimulator::setExternalCameraPosition().

void vpRobotWireFrameSimulator::setGraphicsThickness ( unsigned int  thickness)
inlineinherited

Specify the thickness of the graphics drawings.

Definition at line 311 of file vpRobotWireFrameSimulator.h.

void vpWireFrameSimulator::setInternalCameraParameters ( const vpCameraParameters cam)
inlineinherited

Set the internal camera parameters.

Parameters
cam: The desired camera parameters.
Examples:
servoSimu4Points.cpp, servoSimuCylinder.cpp, servoSimuSphere.cpp, tutorial-ibvs-4pts-wireframe-camera.cpp, and wireframeSimulator.cpp.

Definition at line 509 of file vpWireFrameSimulator.h.

References vpCameraParameters::get_px(), and vpCameraParameters::get_py().

void vpSimulatorAfma6::setJointLimit ( const vpColVector limitMin,
const vpColVector limitMax 
)

This method enables to set the minimum and maximum joint limits for all the six axis of the robot. The three first values have to be given in meter and the others in radian.

Parameters
limitMin: The minimum joint limits are given in a vector of size 6. The three first values have to be given in meter and the others in radian.
limitMax: The maximum joint limits are given in a vector of size 6. The three first values have to be given in meter and the others in radian.
Examples:
servoMomentPoints.cpp, and servoMomentPolygon.cpp.

Definition at line 1838 of file vpSimulatorAfma6.cpp.

References vpAfma6::_joint_max, vpAfma6::_joint_min, vpArray2D< Type >::getRows(), and vpTRACE.

void vpRobot::setMaxRotationVelocity ( const double  w_max)
inherited

Set the maximal rotation velocity that can be sent to the robot during a velocity control.

Parameters
w_max: Maximum rotation velocity expressed in rad/s.
Examples:
servoMomentPoints.cpp, servoSimu4Points.cpp, servoSimuSphere.cpp, and testFeatureSegment.cpp.

Definition at line 262 of file vpRobot.cpp.

Referenced by vpRobotViper650::setMaxRotationVelocity(), vpRobotViper850::setMaxRotationVelocity(), and setPosition().

void vpRobot::setMaxTranslationVelocity ( const double  v_max)
inherited

Set the maximal translation velocity that can be sent to the robot during a velocity control.

Parameters
v_max: Maximum translation velocity expressed in m/s.
Examples:
servoMomentPoints.cpp, servoSimu4Points.cpp, servoSimuSphere.cpp, simulateCircle2DCamVelocity.cpp, simulateFourPoints2DCartesianCamVelocity.cpp, simulateFourPoints2DPolarCamVelocity.cpp, and testFeatureSegment.cpp.

Definition at line 238 of file vpRobot.cpp.

Referenced by setPosition().

void vpWireFrameSimulator::setNbPtTrajectory ( const unsigned int  nbPt)
inlineinherited

Set the maximum number of main camera's positions which are stored. Those position can be displayed in the external camera field of view. By default this parameter is set to 1000.

Parameters
nbPt: The desired number of position which are saved.

Definition at line 519 of file vpWireFrameSimulator.h.

void vpSimulatorAfma6::setPosition ( const vpRobot::vpControlFrameType  frame,
const vpColVector q 
)
virtual

Move to an absolute position with a given percent of max velocity. The percent of max velocity is to set with setPositioningVelocity(). The position to reach can be specified in joint coordinates, in the camera frame or in the reference frame.

Warning
This method is blocking. It returns only when the position is reached by the robot.
Parameters
q: A six dimension vector corresponding to the position to reach. All the positions are expressed in meters for the translations and radians for the rotations. If the position is out of range, an exception is provided.
frame: Frame in which the position is expressed.
  • In the joint space, positions are respectively X, Y, Z, A, B, C, with X,Y,Z the translations, and A,B,C the rotations of the end-effector.
  • In the camera and the reference frame, rotations are represented by a vpRxyzVector.
  • Mixt frame is not implemented. By mixt frame we mean, translations expressed in the reference frame, and rotations in the camera frame.
Exceptions
vpRobotException::lowLevelError: vpRobot::MIXT_FRAME not implemented.
vpRobotException::positionOutOfRangeError: The requested position is out of range.
#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
int main()
{
vpColVector position(6);
// Set positions in the camera frame
position[0] = 0.1; // x axis, in meter
position[1] = 0.2; // y axis, in meter
position[2] = 0.3; // z axis, in meter
position[3] = M_PI/8; // rotation around x axis, in rad
position[4] = M_PI/4; // rotation around y axis, in rad
position[5] = M_PI; // rotation around z axis, in rad
// Set the max velocity to 20%
// Moves the robot in the camera frame
}

To catch the exception if the position is out of range, modify the code like:

try {
}
catch (vpRobotException &e) {
std::cout << "The position is out of range" << std::endl;
}

Implements vpRobot.

Definition at line 1361 of file vpSimulatorAfma6.cpp.

References vpRobot::ARTICULAR_FRAME, vpRobot::CAMERA_FRAME, vpRobotWireFrameSimulator::get_artCoord(), vpAfma6::get_fMc(), vpAfma6::getInverseKinematics(), vpRobot::getRobotState(), vpRobotException::lowLevelError, vpRobot::MIXT_FRAME, vpRobotException::positionOutOfRangeError, vpRobot::REFERENCE_FRAME, vpRobotWireFrameSimulator::set_artCoord(), vpRobotWireFrameSimulator::set_artVel(), vpRobotWireFrameSimulator::set_velocity(), vpRobotWireFrameSimulator::setVelocityCalled, vpRobot::STATE_POSITION_CONTROL, vpColVector::sumSquare(), vpRobotWireFrameSimulator::verbose_, and vpERROR_TRACE.

Referenced by move(), and setPosition().

void vpSimulatorAfma6::setPosition ( const vpRobot::vpControlFrameType  frame,
const double  pos1,
const double  pos2,
const double  pos3,
const double  pos4,
const double  pos5,
const double  pos6 
)

Move to an absolute position with a given percent of max velocity. The percent of max velocity is to set with setPositioningVelocity(). The position to reach can be specified in joint coordinates, in the camera frame or in the reference frame.

This method overloads setPosition(const vpRobot::vpControlFrameType, const vpColVector &).

Warning
This method is blocking. It returns only when the position is reached by the robot.
Parameters
pos1,pos2,pos3,pos4,pos5,pos6: The six coordinates of the position to reach. All the positions are expressed in meters for the translations and radians for the rotations.
frame: Frame in which the position is expressed.
  • In the joint space, positions are respectively X (pos1), Y (pos2), Z (pos3), A (pos4), B (pos5), C (pos6), with X,Y,Z the translations, and A,B,C the rotations of the end-effector.
  • In the camera and the reference frame, rotations [pos4, pos5, pos6] are represented by a vpRxyzVector.
  • Mixt frame is not implemented. By mixt frame we mean, translations expressed in the reference frame, and rotations in the camera frame.
Exceptions
vpRobotException::lowLevelError: vpRobot::MIXT_FRAME not implemented.
vpRobotException::positionOutOfRangeError: The requested position is out of range.
#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
int main()
{
// Set positions in the camera frame
double pos1 = 0.1; // x axis, in meter
double pos2 = 0.2; // y axis, in meter
double pos3 = 0.3; // z axis, in meter
double pos4 = M_PI/8; // rotation around x axis, in rad
double pos5 = M_PI/4; // rotation around y axis, in rad
double pos6 = M_PI; // rotation around z axis, in rad
// Set the max velocity to 20%
// Moves the robot in the camera frame
robot.setPosition(vpRobot::CAMERA_FRAME, pos1, pos2, pos3, pos4, pos5, pos6);
}
See Also
setPosition()

Definition at line 1566 of file vpSimulatorAfma6.cpp.

References setPosition(), and vpERROR_TRACE.

void vpSimulatorAfma6::setPosition ( const char *  filename)

Move to an absolute joint position with a given percent of max velocity. The robot state is set to position control. The percent of max velocity is to set with setPositioningVelocity(). The position to reach is defined in the position file.

Parameters
filename: Name of the position file to read. The readPosFile() documentation shows a typical content of such a position file.

This method has the same behavior than the sample code given below;

#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
int main()
{
robot.readPosFile("MyPositionFilename.pos", q);
}
Exceptions
vpRobotException::lowLevelError: vpRobot::MIXT_FRAME not implemented.
vpRobotException::positionOutOfRangeError: The requested position is out of range.
See Also
setPositioningVelocity()

Definition at line 1627 of file vpSimulatorAfma6.cpp.

References vpRobot::ARTICULAR_FRAME, vpRobotException::lowLevelError, readPosFile(), setPosition(), setRobotState(), vpRobot::STATE_POSITION_CONTROL, and vpERROR_TRACE.

bool vpSimulatorAfma6::setPosition ( const vpHomogeneousMatrix cdMo_,
vpImage< unsigned char > *  Iint = NULL,
const double &  errMax = 0.001 
)

This method enable to move the robot with respect to the initialized object. The robot trajectory is a straight line from the current position to the one corresponding to the desired pose (3D visual servoing).

Parameters
cdMo_: the desired pose of the camera wrt. the object
Iint: pointer to the image where the internal view is displayed
errMax: maximum error to consider the pose is reached
Returns
True is the pose is reached, False else

Definition at line 2590 of file vpSimulatorAfma6.cpp.

References vpThetaUVector::buildFrom(), vpRobot::CAMERA_FRAME, vpDisplay::display(), vpColVector::euclideanNorm(), vpHomogeneousMatrix::extract(), vpDisplay::flush(), vpRobotWireFrameSimulator::get_cMo(), vpRobotWireFrameSimulator::getInternalView(), vpRobot::getMaxRotationVelocity(), vpRobot::getMaxTranslationVelocity(), vpHomogeneousMatrix::inverse(), vpTime::measureTimeMs(), vpRobotWireFrameSimulator::set_artVel(), vpRobotWireFrameSimulator::set_velocity(), vpRobot::setMaxRotationVelocity(), vpRobot::setMaxTranslationVelocity(), setVelocity(), vpRotationMatrix::t(), and vpTime::wait().

void vpSimulatorAfma6::setPositioningVelocity ( const double  vel)
inline

Definition at line 241 of file vpSimulatorAfma6.h.

vpRobot::vpRobotStateType vpSimulatorAfma6::setRobotState ( const vpRobot::vpRobotStateType  newState)
virtual

Change the robot state.

Parameters
newState: New requested robot state.

Reimplemented from vpRobot.

Definition at line 793 of file vpSimulatorAfma6.cpp.

References vpRobot::getRobotState(), vpRobot::setRobotState(), vpRobot::STATE_ACCELERATION_CONTROL, vpRobot::STATE_POSITION_CONTROL, vpRobot::STATE_STOP, vpRobot::STATE_VELOCITY_CONTROL, and stopMotion().

Referenced by init(), move(), and setPosition().

void vpRobotWireFrameSimulator::setSamplingTime ( const double &  delta_t)
inlinevirtualinherited

Set the sampling time.

Parameters
delta_t: Sampling time in second used to compute the robot displacement from the velocity applied to the robot during this time.

Since the wireframe simulator is threaded, the sampling time is set to vpTime::getMinTimeForUsleepCall() / 1000 seconds.

Reimplemented from vpRobotSimulator.

Definition at line 325 of file vpRobotWireFrameSimulator.h.

References vpTime::getMinTimeForUsleepCall().

Referenced by vpRobotWireFrameSimulator::vpRobotWireFrameSimulator().

void vpRobotWireFrameSimulator::setSingularityManagement ( const bool  sm)
inlineinherited

Set the parameter which enable or disable the singularity mangement

Definition at line 334 of file vpRobotWireFrameSimulator.h.

void vpAfma6::setToolType ( vpAfma6::vpAfma6ToolType  tool)
inlineprotectedinherited

Set the current tool type.

Definition at line 189 of file vpAfma6.h.

Referenced by vpAfma6::init(), init(), and vpRobotAfma6::init().

void vpSimulatorAfma6::setVelocity ( const vpRobot::vpControlFrameType  frame,
const vpColVector vel 
)
virtual

Apply a velocity to the robot.

Parameters
frame: Control frame in which the velocity is expressed. Velocities could be expressed in articular, camera frame, reference frame or mixt frame.
vel: Velocity vector. Translation velocities are expressed in m/s while rotation velocities in rad/s. The size of this vector is always 6.
  • In articular, $ vel = [\dot{q}_1, \dot{q}_2, \dot{q}_3, \dot{q}_4, \dot{q}_5, \dot{q}_6]^t $ correspond to joint velocities.
  • In camera frame, $ vel = [^{c} v_x, ^{c} v_y, ^{c} v_z, ^{c} \omega_x, ^{c} \omega_y, ^{c} \omega_z]^t $ is expressed in the camera frame.
  • In reference frame, $ vel = [^{r} v_x, ^{r} v_y, ^{r} v_z, ^{r} \omega_x, ^{r} \omega_y, ^{r} \omega_z]^t $ is expressed in the reference frame.
  • In mixt frame, $ vel = [^{r} v_x, ^{r} v_y, ^{r} v_z, ^{c} \omega_x, ^{c} \omega_y, ^{c} \omega_z]^t $. In mixt frame, translations $ v_x, v_y, v_z $ are expressed in the reference frame and rotations $ \omega_x, \omega_y, \omega_z $ in the camera frame.
Exceptions
vpRobotException::wrongStateError: If a the robot is not configured to handle a velocity. The robot can handle a velocity only if the velocity control mode is set. For that, call setRobotState( vpRobot::STATE_VELOCITY_CONTROL) before setVelocity().
Warning
Velocities could be saturated if one of them exceed the maximal autorized speed (see vpRobot::maxTranslationVelocity and vpRobot::maxRotationVelocity). To change these values use setMaxTranslationVelocity() and setMaxRotationVelocity().
#include <visp3/core/vpConfig.h>
#include <visp3/robot/vpSimulatorAfma6.h>
#include <visp3/core/vpColVector.h>
#include <visp3/core/vpMath.h>
int main()
{
vpColVector qvel(6);
// Set a joint velocity
qvel[0] = 0.1; // Joint 1 velocity in m/s
qvel[1] = 0.1; // Joint 2 velocity in m/s
qvel[2] = 0.1; // Joint 3 velocity in m/s
qvel[3] = M_PI/8; // Joint 4 velocity in rad/s
qvel[4] = 0; // Joint 5 velocity in rad/s
qvel[5] = 0; // Joint 6 velocity in rad/s
// Initialize the controller to position control
for ( ; ; ) {
// Apply a velocity in the joint space
// Compute new velocities qvel...
}
// Stop the robot
}

Implements vpRobot.

Definition at line 897 of file vpSimulatorAfma6.cpp.

References vpRobot::ARTICULAR_FRAME, vpRobot::CAMERA_FRAME, vpRobot::getMaxRotationVelocity(), vpRobot::getMaxTranslationVelocity(), vpRobot::getRobotState(), vpArray2D< Type >::getRows(), vpRobotWireFrameSimulator::jointLimit, vpRobot::MIXT_FRAME, vpRobot::REFERENCE_FRAME, vpRobotWireFrameSimulator::set_velocity(), vpRobot::setRobotFrame(), vpRobotWireFrameSimulator::setVelocityCalled, vpRobot::STATE_VELOCITY_CONTROL, vpERROR_TRACE, and vpRobotException::wrongStateError.

Referenced by setPosition().

void vpRobotWireFrameSimulator::setVerbose ( bool  verbose)
inlineinherited

Activates extra printings when the robot reaches joint limits...

Definition at line 339 of file vpRobotWireFrameSimulator.h.

bool vpSimulatorAfma6::singularityTest ( const vpColVector  q,
vpMatrix J 
)
protected

Test to detect if the robot is near one of its singularities.

The goal is to avoid the problems du to such configurations.

Definition at line 1868 of file vpSimulatorAfma6.cpp.

Referenced by computeArticularVelocity().

void vpSimulatorAfma6::updateArticularPosition ( )
protectedvirtual

Method lauched by the thread to compute the position of the robot in the articular frame.

Implements vpRobotWireFrameSimulator.

Definition at line 521 of file vpSimulatorAfma6.cpp.

References vpAfma6::_joint_max, vpAfma6::_joint_min, vpRobotWireFrameSimulator::cameraParam, compute_fMi(), computeArticularVelocity(), vpRobotWireFrameSimulator::constantSamplingTimeMode, vpMeterPixelConversion::convertPoint(), vpMath::deg(), vpDisplay::display(), vpRobotWireFrameSimulator::displayAllowed, vpDisplay::displayCamera(), vpDisplay::displayFrame(), vpDisplay::displayLine(), vpRobotWireFrameSimulator::displayType, vpDisplay::flush(), vpRobotWireFrameSimulator::fMi, vpRobotWireFrameSimulator::get_artCoord(), vpRobotWireFrameSimulator::get_artVel(), vpRobotWireFrameSimulator::get_displayBusy(), get_fMi(), vpPoint::get_x(), vpPoint::get_y(), vpRobotWireFrameSimulator::getExternalCameraPosition(), getExternalImage(), vpTime::getMinTimeForUsleepCall(), vpRobotSimulator::getSamplingTime(), vpColor::green, vpRobotWireFrameSimulator::I, isInJointLimit(), vpRobotWireFrameSimulator::jointLimit, vpRobotWireFrameSimulator::jointLimitArt, vpTime::measureTimeMs(), vpRobotWireFrameSimulator::MODEL_3D, vpColor::none, vpRobotWireFrameSimulator::robotStop, vpRobotWireFrameSimulator::set_artCoord(), vpRobotWireFrameSimulator::set_artVel(), vpRobotWireFrameSimulator::set_displayBusy(), vpRobotWireFrameSimulator::setVelocityCalled, vpRobotWireFrameSimulator::tcur, vpWireFrameSimulator::thickness_, vpRobotWireFrameSimulator::tprev, vpForwardProjection::track(), vpRobotWireFrameSimulator::verbose_, and vpTime::wait().

Member Data Documentation

vpRxyzVector vpAfma6::_erc
protectedinherited
vpTranslationVector vpAfma6::_etc
protectedinherited
int vpRobot::areJointLimitsAvailable
protectedinherited

Definition at line 109 of file vpRobot.h.

Referenced by vpRobot::operator=().

vpColVector vpRobotWireFrameSimulator::artCoord
protectedinherited

The articular coordinates

Definition at line 113 of file vpRobotWireFrameSimulator.h.

Referenced by init(), and vpSimulatorViper850::init().

vpColVector vpRobotWireFrameSimulator::artVel
protectedinherited

The articular velocity

Definition at line 115 of file vpRobotWireFrameSimulator.h.

Referenced by init(), and vpSimulatorViper850::init().

pthread_attr_t vpRobotWireFrameSimulator::attr
protectedinherited
bool vpWireFrameSimulator::blocked
protectedinherited

Definition at line 224 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::navigation().

bool vpWireFrameSimulator::blockedr
protectedinherited

Definition at line 221 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::navigation().

bool vpWireFrameSimulator::blockedt
protectedinherited

Definition at line 223 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::navigation().

bool vpWireFrameSimulator::blockedz
protectedinherited

Definition at line 222 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::navigation().

vpColor vpWireFrameSimulator::camColor
protectedinherited
float vpWireFrameSimulator::cameraFactor
protectedinherited
vpCameraParameters vpRobotWireFrameSimulator::cameraParam
protectedinherited
std::list<vpImagePoint> vpWireFrameSimulator::cameraTrajectory
protectedinherited
vpHomogeneousMatrix vpWireFrameSimulator::camMf2
protectedinherited
vpColor vpWireFrameSimulator::camTrajColor
protectedinherited
vpCameraTrajectoryDisplayType vpWireFrameSimulator::camTrajType
protectedinherited
vpHomogeneousMatrix vpWireFrameSimulator::cdMo
protectedinherited
const std::string vpAfma6::CONST_AFMA6_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_Afma6.cnf")

File where constant parameters in relation with the robot are stored: joint max, min, coupling factor between 4 ant 5 joint, distance between 5 and 6 joint, tranformation eMc between end-effector and camera frame.

Definition at line 83 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_CAMERA_AFMA6_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_camera_Afma6.xml")

Definition at line 92 of file vpAfma6.h.

Referenced by vpAfma6::getCameraParameters().

const char *const vpAfma6::CONST_CCMOP_CAMERA_NAME = "Dragonfly2-8mm-ccmop"
staticinherited

Name of the camera attached to the CCMOP tool (vpAfma6ToolType::TOOL_CCMOP).

Definition at line 97 of file vpAfma6.h.

Referenced by vpAfma6::getCameraParameters(), and getCameraParameters().

const std::string vpAfma6::CONST_EMC_CCMOP_WITH_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_ccmop_with_distortion_Afma6.cnf")

Definition at line 85 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_EMC_CCMOP_WITHOUT_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_ccmop_without_distortion_Afma6.cnf")

Definition at line 84 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_EMC_GENERIC_WITH_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_generic_with_distortion_Afma6.cnf")

Definition at line 91 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_EMC_GENERIC_WITHOUT_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_generic_without_distortion_Afma6.cnf")

Definition at line 90 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_EMC_GRIPPER_WITH_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_gripper_with_distortion_Afma6.cnf")

Definition at line 87 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_EMC_GRIPPER_WITHOUT_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_gripper_without_distortion_Afma6.cnf")

Definition at line 86 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_EMC_VACUUM_WITH_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_vacuum_with_distortion_Afma6.cnf")

Definition at line 89 of file vpAfma6.h.

Referenced by vpAfma6::init().

const std::string vpAfma6::CONST_EMC_VACUUM_WITHOUT_DISTORTION_FILENAME
staticinherited
Initial value:
=
std::string(VISP_AFMA6_DATA_PATH) + std::string("/include/const_eMc_vacuum_without_distortion_Afma6.cnf")

Definition at line 88 of file vpAfma6.h.

Referenced by vpAfma6::init().

const char *const vpAfma6::CONST_GENERIC_CAMERA_NAME = "Generic-camera"
staticinherited

Name of the generic camera attached to the robot hand (vpAfma6ToolType::TOOL_GENERIC_CAMERA).

Definition at line 112 of file vpAfma6.h.

Referenced by vpAfma6::getCameraParameters().

const char *const vpAfma6::CONST_GRIPPER_CAMERA_NAME = "Dragonfly2-6mm-gripper"
staticinherited

Name of the camera attached to the 2 fingers gripper tool (vpAfma6ToolType::TOOL_GRIPPER).

Definition at line 102 of file vpAfma6.h.

Referenced by vpAfma6::getCameraParameters(), and getCameraParameters().

const char *const vpAfma6::CONST_VACUUM_CAMERA_NAME = "Dragonfly2-6mm-vacuum"
staticinherited

Name of the camera attached to the vacuum gripper tool (vpAfma6ToolType::TOOL_VACUUM).

Definition at line 107 of file vpAfma6.h.

Referenced by vpAfma6::getCameraParameters().

bool vpRobotWireFrameSimulator::constantSamplingTimeMode
protectedinherited

Flag used to force the sampling time in the thread computing the robot's displacement to a constant value (samplingTime). It may be useful if the main thread (computing the features) is very time consumming. False by default.

Definition at line 166 of file vpRobotWireFrameSimulator.h.

Referenced by updateArticularPosition(), and vpSimulatorViper850::updateArticularPosition().

const double vpSimulatorAfma6::defaultPositioningVelocity = 25.0
static

Definition at line 179 of file vpSimulatorAfma6.h.

Referenced by init().

const vpAfma6::vpAfma6ToolType vpAfma6::defaultTool = TOOL_CCMOP
staticinherited

Default tool attached to the robot end effector.

Definition at line 125 of file vpAfma6.h.

Referenced by vpAfma6::init(), and vpRobotAfma6::init().

double vpRobotSimulator::delta_t_
protectedinherited
vpColor vpWireFrameSimulator::desColor
protectedinherited
vpSceneDesiredObject vpWireFrameSimulator::desiredObject
protectedinherited
vpDisplayX vpRobotWireFrameSimulator::display
protectedinherited
bool vpRobotWireFrameSimulator::displayAllowed
protectedinherited
bool vpRobotWireFrameSimulator::displayBusy
protectedinherited

Definition at line 136 of file vpRobotWireFrameSimulator.h.

bool vpWireFrameSimulator::displayCameraTrajectory
protectedinherited

Definition at line 212 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::getExternalImage().

bool vpWireFrameSimulator::displayImageSimulator
protectedinherited
vpDisplayRobotType vpRobotWireFrameSimulator::displayType
protectedinherited
vpMatrix vpRobot::eJe
protectedinherited

robot Jacobian expressed in the end-effector frame

Definition at line 101 of file vpRobot.h.

Referenced by vpSimulatorCamera::get_eJe(), vpRobotCamera::get_eJe(), vpRobot::operator=(), and vpRobotAfma4::setVelocity().

int vpRobot::eJeAvailable
protectedinherited

is the robot Jacobian expressed in the end-effector frame available

Definition at line 103 of file vpRobot.h.

Referenced by vpRobot::operator=().

bool vpWireFrameSimulator::extCamChanged
protectedinherited

Definition at line 243 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::getExternalImage().

vpHomogeneousMatrix vpWireFrameSimulator::f2Mf
protectedinherited
vpMatrix vpRobot::fJe
protectedinherited

robot Jacobian expressed in the robot reference frame available

Definition at line 105 of file vpRobot.h.

Referenced by vpRobot::operator=().

int vpRobot::fJeAvailable
protectedinherited

is the robot Jacobian expressed in the robot reference frame available

Definition at line 107 of file vpRobot.h.

Referenced by vpRobot::operator=().

vpHomogeneousMatrix vpWireFrameSimulator::fMc
protectedinherited

Definition at line 196 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::getExternalImage().

vpHomogeneousMatrix* vpRobotWireFrameSimulator::fMi
protectedinherited

Table containing all the homogeneous matrices between the reference frame of the robot and the frames you used to compute the Denavit-Hartenberg representation

If you use a camera at the end of the effector, the last homogeneous matrix has to be the one between the reference frame and the camera frame (fMc)

Definition at line 110 of file vpRobotWireFrameSimulator.h.

Referenced by compute_fMi(), vpSimulatorViper850::compute_fMi(), init(), vpSimulatorViper850::init(), updateArticularPosition(), vpSimulatorViper850::updateArticularPosition(), ~vpSimulatorAfma6(), and vpSimulatorViper850::~vpSimulatorViper850().

std::list<vpHomogeneousMatrix> vpWireFrameSimulator::fMoList
protectedinherited
bool vpRobotWireFrameSimulator::jointLimit
protectedinherited
unsigned int vpRobotWireFrameSimulator::jointLimitArt
protectedinherited

Index of the joint which is in limit

Definition at line 143 of file vpRobotWireFrameSimulator.h.

Referenced by updateArticularPosition(), and vpSimulatorViper850::updateArticularPosition().

double vpRobot::maxRotationVelocity
protectedinherited
const double vpRobot::maxRotationVelocityDefault = 0.7
staticprotectedinherited

Definition at line 96 of file vpRobot.h.

double vpRobot::maxTranslationVelocity
protectedinherited

Definition at line 93 of file vpRobot.h.

Referenced by vpRobot::operator=().

const double vpRobot::maxTranslationVelocityDefault = 0.2
staticprotectedinherited

Definition at line 94 of file vpRobot.h.

pthread_mutex_t vpRobotWireFrameSimulator::mutex_artCoord
protectedinherited
pthread_mutex_t vpRobotWireFrameSimulator::mutex_artVel
protectedinherited
pthread_mutex_t vpRobotWireFrameSimulator::mutex_display
protectedinherited
pthread_mutex_t vpRobotWireFrameSimulator::mutex_fMi
protectedinherited
pthread_mutex_t vpRobotWireFrameSimulator::mutex_velocity
protectedinherited
unsigned int vpWireFrameSimulator::nbrPtLimit
protectedinherited

Definition at line 216 of file vpWireFrameSimulator.h.

Referenced by vpWireFrameSimulator::getExternalImage().

int vpRobot::nDof
protectedinherited

number of degrees of freedom

Definition at line 99 of file vpRobot.h.

Referenced by vpRobot::operator=().

vpSceneObject vpWireFrameSimulator::object
protectedinherited

Definition at line 202 of file vpWireFrameSimulator.h.

std::list<vpImageSimulator> vpWireFrameSimulator::objectImage
protectedinherited
vpImagePoint vpWireFrameSimulator::old_iPr
protectedinherited
vpImagePoint vpWireFrameSimulator::old_iPt
protectedinherited
vpImagePoint vpWireFrameSimulator::old_iPz
protectedinherited
std::list<vpHomogeneousMatrix> vpWireFrameSimulator::poseList
protectedinherited
vpCameraParameters::vpCameraParametersProjType vpAfma6::projModel
protectedinherited

Definition at line 214 of file vpAfma6.h.

Referenced by vpAfma6::getCameraParameters(), vpAfma6::init(), and init().

double vpWireFrameSimulator::px_ext
protectedinherited
double vpWireFrameSimulator::py_ext
protectedinherited
double* vpRobot::qmax
protectedinherited

Definition at line 111 of file vpRobot.h.

Referenced by vpRobot::operator=(), and vpRobot::~vpRobot().

double* vpRobot::qmin
protectedinherited

Definition at line 110 of file vpRobot.h.

Referenced by vpRobot::operator=(), and vpRobot::~vpRobot().

vpHomogeneousMatrix vpWireFrameSimulator::refMo
protectedinherited

Definition at line 198 of file vpWireFrameSimulator.h.

Bound_scene* vpRobotWireFrameSimulator::robotArms
protectedinherited
bool vpRobotWireFrameSimulator::robotStop
protectedinherited
bool vpRobotWireFrameSimulator::setVelocityCalled
protectedinherited

Flag used to specify to the thread managing the robot displacements that the setVelocity() method has been called.

Definition at line 169 of file vpRobotWireFrameSimulator.h.

Referenced by setPosition(), vpSimulatorViper850::setPosition(), setVelocity(), vpSimulatorViper850::setVelocity(), updateArticularPosition(), and vpSimulatorViper850::updateArticularPosition().

bool vpRobotWireFrameSimulator::singularityManagement
protectedinherited

True if the singularity are automatically managed

Definition at line 145 of file vpRobotWireFrameSimulator.h.

Referenced by computeArticularVelocity(), and vpSimulatorViper850::computeArticularVelocity().

unsigned int vpRobotWireFrameSimulator::size_fMi
protectedinherited
double vpRobotWireFrameSimulator::tcur
protectedinherited
pthread_t vpRobotWireFrameSimulator::thread
protectedinherited
vpAfma6ToolType vpAfma6::tool_current
protectedinherited

Current tool in use.

Definition at line 212 of file vpAfma6.h.

double vpRobotWireFrameSimulator::tprev
protectedinherited

cpu time at the end of the last robot's movement

Definition at line 100 of file vpRobotWireFrameSimulator.h.

Referenced by updateArticularPosition(), and vpSimulatorViper850::updateArticularPosition().

vpColVector vpRobotWireFrameSimulator::velocity
protectedinherited

The velocity in the current frame (articular, camera or reference)

Definition at line 117 of file vpRobotWireFrameSimulator.h.

Referenced by vpRobotWireFrameSimulator::vpRobotWireFrameSimulator().