sim_cinematique_inverse/labo_ik/IKSolver.cpp

#pragma once

#include <cfloat>
#include "IKSolver.h"
#include "Armature.h"
#include "SVD.h"

using namespace gti320;

namespace {
}

IKSolver::IKSolver(Armature *_armature, Vector3f &_targetPos) : m_armature(_armature), m_targetPos(_targetPos), m_J() {
}


float IKSolver::getError(Vector3f &dx) const {
    // TODO Compute the error between the current end effector 
    //      position and the target position
    dx.setZero();

    const int numLinks = m_armature->links.size();
    Link *endEffector = m_armature->links[numLinks - 1];

    Vector3f f_theta = endEffector->globalPosition();
    Vector3f ddx = m_targetPos - f_theta;
    dx(0) = ddx(0);
    dx(1) = ddx(1);
    dx(2) = ddx(2);

    return ddx.norm();
}

void jacobian(Jacobianf &m_J, Link *link, Vector3f &ri, int i) {
    // axes x, y et z
    for (int j = 0; j < 3; j++) {
        // crossP
        m_J(0, i) = link->M(j, 1) * ri(2) - link->M(j, 2) * ri(1);
        m_J(1, i) = link->M(j, 0) * ri(2) - link->M(j, 2) * ri(0);
        m_J(2, i) = link->M(j, 0) * ri(1) - link->M(j, 1) * ri(0);
    }
}

void IKSolver::solve() {
    const int numLinks = m_armature->links.size();
    const int dim = 3 * (numLinks);
    m_J.resize(3, dim);

    // We assume that the last link is the "end effector"
    //
    Link *endEffector = m_armature->links[numLinks - 1];

    // Build the Jacobian matrix m_J.
    //      Each column corresponds to a separate link
    for (int i = 0; i < numLinks; i++) {
        Link *link = m_armature->links[i];
        Vector3f shift = endEffector->globalPosition() - link->globalPosition();

        jacobian(m_J, link, shift, i);
    }

    // TODO Compute the error between the current end effector 
    //      position and the target position by calling getError()
    Vector3f dx;
    float error = getError(dx);

    // TODO Compute the change in the joint angles by solving:
    //    df/dtheta * delta_theta = delta_x
    //  where df/dtheta is the Jacobian matrix.
    //    
    //

    // TODO Perform gradient descent method with line search
    //      to move the end effector toward the target position.
    //
    //   Hint: use the Armature::unpack() and Armature::pack() functions
    //   to set and get the joint angles of the armature.
    // 
    //   Hint: whenever you change the joint angles, you must also call
    //   armature->updateKinematics() to compute the global position.
    //    

}
Init 2024-04-01 17:18:18 -04:00			`#pragma once`

Replace non-standard itoa() to std::to_string() 2024-04-06 17:19:19 -04:00			`#include <cfloat>`
Init 2024-04-01 17:18:18 -04:00			`#include "IKSolver.h"`
			`#include "Armature.h"`
			`#include "SVD.h"`

			`using namespace gti320;`

Matrice jacobienne 2024-04-06 20:50:36 -04:00			`namespace {`
Init 2024-04-01 17:18:18 -04:00			`}`

Matrice jacobienne 2024-04-06 20:50:36 -04:00			`IKSolver::IKSolver(Armature *_armature, Vector3f &_targetPos) : m_armature(_armature), m_targetPos(_targetPos), m_J() {`
Init 2024-04-01 17:18:18 -04:00			`}`


Matrice jacobienne 2024-04-06 20:50:36 -04:00			`float IKSolver::getError(Vector3f &dx) const {`
Init 2024-04-01 17:18:18 -04:00			`// TODO Compute the error between the current end effector`
Matrice jacobienne 2024-04-06 20:50:36 -04:00			`// position and the target position`
Init 2024-04-01 17:18:18 -04:00			`dx.setZero();`
Matrice jacobienne 2024-04-06 20:50:36 -04:00
			`const int numLinks = m_armature->links.size();`
			`Link *endEffector = m_armature->links[numLinks - 1];`

			`Vector3f f_theta = endEffector->globalPosition();`
			`Vector3f ddx = m_targetPos - f_theta;`
			`dx(0) = ddx(0);`
			`dx(1) = ddx(1);`
			`dx(2) = ddx(2);`

			`return ddx.norm();`
Init 2024-04-01 17:18:18 -04:00			`}`

Matrice jacobienne 2024-04-06 20:50:36 -04:00			`void jacobian(Jacobianf &m_J, Link *link, Vector3f &ri, int i) {`
			`// axes x, y et z`
			`for (int j = 0; j < 3; j++) {`
			`// crossP`
			`m_J(0, i) = link->M(j, 1) * ri(2) - link->M(j, 2) * ri(1);`
			`m_J(1, i) = link->M(j, 0) * ri(2) - link->M(j, 2) * ri(0);`
			`m_J(2, i) = link->M(j, 0) * ri(1) - link->M(j, 1) * ri(0);`
			`}`
			`}`

			`void IKSolver::solve() {`
Init 2024-04-01 17:18:18 -04:00			`const int numLinks = m_armature->links.size();`
			`const int dim = 3 * (numLinks);`
			`m_J.resize(3, dim);`

			`// We assume that the last link is the "end effector"`
			`//`
Matrice jacobienne 2024-04-06 20:50:36 -04:00			`Link *endEffector = m_armature->links[numLinks - 1];`
Init 2024-04-01 17:18:18 -04:00
Matrice jacobienne 2024-04-06 20:50:36 -04:00			`// Build the Jacobian matrix m_J.`
			`// Each column corresponds to a separate link`
			`for (int i = 0; i < numLinks; i++) {`
			`Link *link = m_armature->links[i];`
			`Vector3f shift = endEffector->globalPosition() - link->globalPosition();`

			`jacobian(m_J, link, shift, i);`
			`}`
Init 2024-04-01 17:18:18 -04:00
			`// TODO Compute the error between the current end effector`
			`// position and the target position by calling getError()`
Matrice jacobienne 2024-04-06 20:50:36 -04:00			`Vector3f dx;`
			`float error = getError(dx);`
Init 2024-04-01 17:18:18 -04:00
			`// TODO Compute the change in the joint angles by solving:`
			`// df/dtheta * delta_theta = delta_x`
			`// where df/dtheta is the Jacobian matrix.`
			`//`
			`//`

			`// TODO Perform gradient descent method with line search`
			`// to move the end effector toward the target position.`
			`//`
			`// Hint: use the Armature::unpack() and Armature::pack() functions`
			`// to set and get the joint angles of the armature.`
			`//`
			`// Hint: whenever you change the joint angles, you must also call`
			`// armature->updateKinematics() to compute the global position.`
			`//`

			`}`