def _populate_strafe(self, num_times, strafe_distance):
        self._update_starting_stance()

        lf_stance = Footstep()
        rf_stance = Footstep()
        mf_stance = copy.deepcopy(self._mf_stance)
        mf_stance_translated = copy.deepcopy(self._mf_stance)

        for i in range(num_times):
            mf_stance_translated.pos = mf_stance.pos + np.dot(
                mf_stance.rot, np.array([0., strafe_distance, 0.]))
            mf_stance_translated.rot = mf_stance.rot

            lf_stance.pos = mf_stance_translated.pos + np.dot(
                mf_stance_translated.rot,
                np.array([0., self._nominal_footwidth / 2., 0.]))
            lf_stance.rot = mf_stance_translated.rot
            lf_stance.side = Footstep.LEFT_SIDE

            rf_stance.pos = mf_stance_translated.pos + np.dot(
                mf_stance_translated.rot,
                np.array([0., -self._nominal_footwidth / 2., 0.]))
            rf_stance.rot = mf_stance_translated.rot
            rf_stance.side = Footstep.RIGHT_SIDE

            if strafe_distance > 0:
                self._footstep_list.append(copy.deepcopy(lf_stance))
                self._footstep_list.append(copy.deepcopy(rf_stance))
            else:
                self._footstep_list.append(copy.deepcopy(rf_stance))
                self._footstep_list.append(copy.deepcopy(lf_stance))
            mf_stance = copy.deepcopy(mf_stance_translated)
    def _populate_turn(self, num_times, turn_radians_per_step):
        self._update_starting_stance()

        foot_rotation = R.from_rotvec([0., 0.,
                                       turn_radians_per_step]).as_matrix()

        lf_stance = Footstep()
        rf_stance = Footstep()
        mf_stance = copy.deepcopy(self._mf_stance)
        mf_stance_rotated = copy.deepcopy(self._mf_stance)

        for i in range(num_times):
            mf_stance_rotated.pos = np.copy(mf_stance.pos)
            mf_stance_rotated.rot = np.dot(foot_rotation, mf_stance.rot)

            lf_stance.pos = mf_stance_rotated.pos + np.dot(
                mf_stance_rotated.rot,
                np.array([0., self._nominal_footwidth / 2., 0.]))
            lf_stance.rot = np.copy(mf_stance_rotated.rot)
            lf_stance.side = Footstep.LEFT_SIDE

            rf_stance.pos = mf_stance_rotated.pos + np.dot(
                mf_stance_rotated.rot,
                np.array([0., -self._nominal_footwidth / 2., 0.]))
            rf_stance.rot = np.copy(mf_stance_rotated.rot)
            rf_stance.side = Footstep.RIGHT_SIDE

            if turn_radians_per_step > 0.:
                self._footstep_list.append(copy.deepcopy(lf_stance))
                self._footstep_list.append(copy.deepcopy(rf_stance))
            else:
                self._footstep_list.append(copy.deepcopy(rf_stance))
                self._footstep_list.append(copy.deepcopy(lf_stance))
            mf_stance = copy.deepcopy(mf_stance_rotated)
Exemple #3
0
    def __init__(self, pos_task, robot):
        self._pos_task = pos_task
        self._robot = robot

        self._swing_start_time = 0.
        self._swing_duration = 0.

        self._swing_init_foot = Footstep()
        self._swing_mid_foot = Footstep()
        self._swing_land_foot = Footstep()

        self._pos_traj_init_to_mid = None
        self._pos_traj_mid_to_end = None

        self._target_id = self._pos_task.target_id

        # Attribute
        self._swing_height = 0.05
    def __init__(self, dcm_planner, com_task, base_ori_task, robot, lfoot_id,
                 rfoot_id):
        self._dcm_planner = dcm_planner
        self._com_task = com_task
        self._base_ori_task = base_ori_task
        self._robot = robot
        self._lfoot_id = lfoot_id
        self._rfoot_id = rfoot_id

        self._des_com_pos = np.zeros(3)
        self._des_com_vel = np.zeros(3)
        self._des_com_acc = np.zeros(3)

        self._des_quat = np.array([0., 0., 0., 1.])
        self._des_ang_vel = np.zeros(3)
        self._des_ang_acc = np.zeros(3)

        self._reset_step_idx()

        self._robot_side = Footstep.RIGHT_SIDE

        self._footstep_list = []
        self._footstep_preview_list = []

        self._lf_stance = Footstep()
        self._rf_stance = Footstep()
        self._mf_stance = Footstep()

        # Attributes
        self._nominal_com_height = 1.015
        self._t_additional_init_transfer = 0.
        self._t_contact_transition = 0.45
        self._t_swing = 1.
        self._percentage_settle = 0.99
        self._alpha_ds = 0.5
        self._nominal_footwidth = 0.27
        self._nominal_forward_step = 0.25
        self._nominal_backward_step = -0.25
        self._nominal_turn_radians = np.pi / 4.
        self._nominal_strafe_distance = 0.125

        self._set_temporal_params()
Exemple #5
0
    def __init__(self):
        self._ini_lf_stance = Footstep()
        self._ini_rf_stance = Footstep()
        self._ini_dcm_pos = np.zeros(3)
        self._ini_dcm_vel = np.zeros(3)

        self._vrp_list = []  # vrp
        self._vrp_type_list = []

        # Attributes
        self._t_transfer = 0.1
        self._t_ds = 0.05
        self._t_ss = 0.3
        self._percentage_settle = 0.99
        self._alpha_ds = 0.5

        self._t_start = 0.
        self._t_end = 0.
        self._dt = 1e-3

        self._z_vrp = 0.75  # com height
        self._b = np.sqrt(self._z_vrp / 9.81)
        self._robot_mass = 50
        self._ini_quat = np.array([0., 0., 0., 1])
    def _populate_walk_forward(self, num_steps, forward_distance):
        self._update_starting_stance()

        new_stance = Footstep()
        mf_stance = copy.deepcopy(self._mf_stance)

        robot_side = Footstep.LEFT_SIDE
        for i in range(num_steps):
            if robot_side == Footstep.LEFT_SIDE:
                translate = np.array([(i + 1) * forward_distance,
                                      self._nominal_footwidth / 2., 0.])
                new_stance.pos = mf_stance.pos + np.dot(
                    mf_stance.rot, translate)
                new_stance.rot = np.copy(mf_stance.rot)
                new_stance.side = Footstep.LEFT_SIDE
                robot_side = Footstep.RIGHT_SIDE
            else:
                translate = np.array([(i + 1) * forward_distance,
                                      -self._nominal_footwidth / 2., 0.])
                new_stance.pos = mf_stance.pos + np.dot(
                    mf_stance.rot, translate)
                new_stance.rot = np.copy(mf_stance.rot)
                new_stance.side = Footstep.RIGHT_SIDE
                robot_side = Footstep.LEFT_SIDE
            self._footstep_list.append(copy.deepcopy(new_stance))

        # Add additional step forward to square the feet
        if robot_side == Footstep.LEFT_SIDE:
            translate = np.array([
                num_steps * forward_distance, self._nominal_footwidth / 2., 0.
            ])
            new_stance.pos = mf_stance.pos + np.dot(mf_stance.rot, translate)
            new_stance.rot = mf_stance.rot
            new_stance.side = Footstep.LEFT_SIDE
        else:
            translate = np.array([
                num_steps * forward_distance, -self._nominal_footwidth / 2., 0.
            ])
            new_stance.pos = mf_stance.pos + np.dot(mf_stance.rot, translate)
            new_stance.rot = mf_stance.rot
            new_stance.side = Footstep.RIGHT_SIDE
        self._footstep_list.append(copy.deepcopy(new_stance))
Exemple #7
0
import os
import sys
cwd = os.getcwd()
sys.path.append(cwd)
import numpy as np

from pnc.planner.locomotion.dcm_planner.footstep import Footstep
from pnc.planner.locomotion.dcm_planner.dcm_planner import DCMPlanner

step_one = Footstep()
step_one.pos = np.array([0.274672, 0.134096, -4.51381e-05])
step_one.quat = np.array([1.89965e-05, 9.56242e-05, -0.000503418, 1])
step_one.side = Footstep.LEFT_SIDE

step_two = Footstep()
step_two.pos = np.array([0.5244, -0.136156, -0.000103187])
step_two.quat = np.array([1.89965e-05, 9.56242e-05, -0.000503418, 1])
step_two.side = Footstep.RIGHT_SIDE

step_third = Footstep()
step_third.pos = np.array([0.524672, 0.133844, -9.2955e-05])
step_third.quat = np.array([1.89965e-05, 9.56242e-05, -0.000503418, 1])
step_third.side = Footstep.LEFT_SIDE

lf_stance = Footstep()
lf_stance.pos = np.array([0.0242475, 0.133069, 5.2579e-09])
lf_stance.quat = np.array([-5.63289e-08, 7.08106e-06, 0.00179564, 0.999998])
lf_stance.side = Footstep.LEFT_SIDE

rf_stance = Footstep()
rf_stance.pos = np.array([0.0248257, -0.134374, -4.11672e-06])
Exemple #8
0
## =============================================================================
## Main
## =============================================================================

initial_dcm = np.array([0., 0., 0.765])

dcm_planner = DCMPlanner()
dcm_planner.t_transfer = 0.
dcm_planner.t_ds = 0.45
dcm_planner.t_ss = 0.75
dcm_planner.percentage_settle = 0.9
dcm_planner.alpha_ds = 0.5
dcm_planner.robot_mass = 100.
dcm_planner.z_vrp = 0.765

lf_stance = Footstep()
lf_stance.pos = np.array([0., 0.11, 0.])
lf_stance.quat = np.array([0., 0., 0., 1.])
lf_stance.side = Footstep.LEFT_SIDE

rf_stance = Footstep()
rf_stance.pos = np.array([0., -0.11, 0.])
rf_stance.quat = np.array([0., 0., 0., 1.])
rf_stance.side = Footstep.RIGHT_SIDE

first_step = Footstep()
first_step.pos = np.array([0.15, 0.11, 0.])
first_step.quat = np.array([0., 0., 0., 1.])
first_step.side = Footstep.LEFT_SIDE

second_step = Footstep()