humotion

/*

* This file is part of humotion

*

* Copyright(c) sschulz <AT> techfak.uni-bielefeld.de

* http://opensource.cit-ec.de/projects/humotion

*

* This file may be licensed under the terms of the

* GNU Lesser General Public License Version 3 (the ``LGPL''),

* or (at your option) any later version.

*

* Software distributed under the License is distributed

* on an ``AS IS'' basis, WITHOUT WARRANTY OF ANY KIND, either

* express or implied. See the LGPL for the specific language

* governing rights and limitations.

*

* You should have received a copy of the LGPL along with this

* program. If not, go to http://www.gnu.org/licenses/lgpl.html

* or write to the Free Software Foundation, Inc.,

* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.

*

* The development of this software was supported by the

* Excellence Cluster EXC 277 Cognitive Interaction Technology.

* The Excellence Cluster EXC 277 is a grant of the Deutsche

* Forschungsgemeinschaft (DFG) in the context of the German

* Excellence Initiative.

*/

#include <cmath>

#include "humotion/server/gaze_motion_generator.h"

#include "humotion/server/neck_motion_generator.h"

#include "humotion/server/server.h"

using humotion::server::NeckMotionGenerator;

using humotion::server::Config;

//! constructor

NeckMotionGenerator::NeckMotionGenerator(JointInterface *j, Config *cfg) :

    GazeMotionGenerator(j, cfg, 3, 1.0/Server::MOTION_UPDATERATE) {

    breath_time_ = 0.0;

}

//! destructor

NeckMotionGenerator::~NeckMotionGenerator() {

}

//! get a breath offset angle

//! @return float of breath offset value

float NeckMotionGenerator::get_breath_offset() {

    // we want to have a constant acceleration

    // -> triangular wave as speeds -> (x<0.5)? 2*x*x:  1- 2*(1-x)**2 = 4x - 2x**2 - 1

    float breath_offset = 0.0;

    // 0...1 -> move up, 1..2 -> return, 2..3 -> still

    float breath_time_normalized = (breath_time_ * 3)/config->breath_period;

    if (breath_time_normalized <= 0.5) {

        // accelerated motion

        breath_offset = config->breath_amplitude * (2.0 * pow(breath_time_normalized, 2));

    } else if (breath_time_normalized <= 1.0) {

        // deaccelerate

        breath_offset = config->breath_amplitude * (1.0 - 2.0

                                                    * pow(1.0 - breath_time_normalized, 2));

    } else if (breath_time_normalized <= 1.5) {

        // accelerate again

        breath_offset = config->breath_amplitude * (1.0 - (2.0 * pow(breath_time_normalized-1, 2)));

    } else if (breath_time_normalized <= 2.0) {

        breath_offset = config->breath_amplitude * (2.0 * pow(2.0 - breath_time_normalized, 2));

    } else if (breath_time_normalized <= 3.0) {

        // pause for some time

        breath_offset = 0;

    }

    // fetch next time

    breath_time_ += 1.0/Server::MOTION_UPDATERATE;

    if (breath_time_ >= config->breath_period) {

        breath_time_ -= config->breath_period;

    }

    return breath_offset;

}

//! calculate joint targets

void NeckMotionGenerator::calculate_targets() {

    // fetch current dataset

    float neck_pan_now, neck_tilt_now, neck_roll_now;

    float neck_pan_speed, neck_tilt_speed, neck_roll_speed;

    humotion::Timestamp neck_pan_ts = get_timestamped_state(JointInterface::ID_NECK_PAN,

                                                            &neck_pan_now,

                                                            &neck_pan_speed);

    humotion::Timestamp neck_tilt_ts = get_timestamped_state(JointInterface::ID_NECK_TILT,

                                                            &neck_tilt_now,

                                                            &neck_tilt_speed);

    humotion::Timestamp neck_roll_ts = get_timestamped_state(JointInterface::ID_NECK_ROLL,

                                                            &neck_roll_now,

                                                            &neck_roll_speed);

    // reached target?

    float goal_diff   = fabs(get_current_gaze().distance_pt_abs(requested_gaze_state_));

    float target_diff = fabs(requested_gaze_state_.distance_pt_abs(previous_neck_target_));

    // printf("GOAL DIFF = %f TARGET DIFF = %f\n",goal_diff,target_diff);

    // get_current_gaze().dump();

    // requested_gaze_state.dump();

    // check if new target

    // close to goal?

    if ( (neck_saccade_active_) && (goal_diff < 1.0) ) {

        neck_saccade_reached_goal_ = true;

    }

    if (neck_saccade_active_) {

        previous_neck_target_ = requested_gaze_state_;

    }

    // if we get a new target now, we can stop the neck saccade

    if (target_diff > .1) {

        if (neck_saccade_reached_goal_) {

            // joint_interface->neck_saccade_done();

            neck_saccade_active_ = false;

            neck_saccade_reached_goal_ = false;

        }

    }

    if (neck_saccade_requested) {

        neck_saccade_active_ = true;

    }

    // check if this is a small or big saccade

    if (neck_saccade_active_ || neck_saccade_omr) {

        // full saccade with neck motion -> update neck target

        requested_neck_state_ = requested_gaze_state_;

    }

    // get targets: this is the sum of stored neck target and up-to-date offset:

    float neck_pan_target  = requested_neck_state_.pan  + requested_gaze_state_.pan_offset;

    float neck_tilt_target = requested_neck_state_.tilt + requested_gaze_state_.tilt_offset;

    // roll is always equal to requested gaze (not neck) state

    float neck_roll_target = requested_gaze_state_.roll + requested_gaze_state_.roll_offset;

    // add breath wave to tilt

    neck_tilt_target += get_breath_offset();

    // pass parameters to reflexxes api

    setup_neckmotion(0, neck_pan_target,  neck_pan_now,  neck_pan_speed,  neck_pan_ts);

    setup_neckmotion(1, neck_tilt_target, neck_tilt_now, neck_tilt_speed, neck_tilt_ts);

    setup_neckmotion(2, neck_roll_target, neck_roll_now, neck_roll_speed, neck_roll_ts);

    // call reflexxes to handle profile calculation

    reflexxes_calculate_profile();

    // tell the joint if about the new values

    joint_interface_->set_target(JointInterface::ID_NECK_PAN,

                                reflexxes_position_output->NewPositionVector->VecData[0],

                                reflexxes_position_output->NewVelocityVector->VecData[0]);

    joint_interface_->set_target(JointInterface::ID_NECK_TILT,

                                reflexxes_position_output->NewPositionVector->VecData[1],

                                reflexxes_position_output->NewVelocityVector->VecData[1]);

    joint_interface_->set_target(JointInterface::ID_NECK_ROLL,

                                reflexxes_position_output->NewPositionVector->VecData[2],

                                reflexxes_position_output->NewVelocityVector->VecData[2]);

    /*printf("\n%f %f %f %f %f DBG\n",

            neck_pan_now, neck_pan_target,

            reflexxes_position_output->NewPositionVector->VecData[0],

            joint_interface->get_ts_speed(JointInterface::ID_NECK_PAN).get_newest_value(),

            reflexxes_position_output->NewVelocityVector->VecData[0]

            );*/

}

//! publish targets to motor boards:

void NeckMotionGenerator::publish_targets() {

    // publish values if there is an active gaze input within the last timerange

    if (gaze_target_input_active()) {

        joint_interface_->publish_target(JointInterface::ID_NECK_PAN);

        joint_interface_->publish_target(JointInterface::ID_NECK_TILT);

        joint_interface_->publish_target(JointInterface::ID_NECK_ROLL);

    }

}

//! set up neck motion profile

//! this will use speed and acceleration calc formulas from literature:

//! \param dof id of joint

//! \param target angle

//! \param current angle

void NeckMotionGenerator::setup_neckmotion(int dof, float target, float current_position,

                                           float current_velocity, humotion::Timestamp timestamp) {

    // get distance to target

    float distance_abs = fabs(target - current_position);

    // get max speed: according to the equation Hmax from [guitton87] there is a linear relation

    // between distance_abs and v_max_head:

    // v_max = 4.39 * d_total + 106.0 (in degrees)

    float max_velocity = 4.39 * distance_abs + 106.0;

    // scale and limit max speed:

    max_velocity = max_velocity * config->scale_velocity_neck;

    max_velocity = fmin(max_velocity, config->limit_velocity_neck);

    // max accel: assuming linear acceleration we have:

    /* v ^  _

    *   |  / \

    *   | /   \

    *   |/_____\___> t

    */

    // d_total = 2 * 1/2 * a * (t_total/2)^2 = 1/4 * a * t_total^2

    // as we use linear accel we have

    // v_max = a * t_total/2  --> t_total = 2*v_max / a

    // combine both

    // d_total = 1/4 * a * 4 * vmax^2 / a^2 = v_max^2 / a

    // d_total = a * 2 * d_total / (v_max^2)

    // and therefore

    // a = v_max^2 / d_total

    float max_accel = 0.0;

    if (distance_abs > 0.0) {

        max_accel = pow(max_velocity, 2) / distance_abs;

    }

    // scale and limit acceleration

    max_accel = max_accel * config->scale_acceleration_neck;

    max_accel = fmin(max_accel, config->limit_acceleration_neck);

    // printf("MAX SPEED %4.2f / max accel %4.2f\n",max_speed, max_accel);

    // feed reflexxes api with data

    reflexxes_set_input(dof, target, current_position, current_velocity,

                        timestamp, max_velocity, max_accel);

}