def compute_orientation_properties(legs, tol=1):
    """
    Returns:
      - Which legs are on the ground
      - Normal vector of the plane defined by these legs
      - Distance of this plane to center of gravity
    """
    trio = three_ids_of_ground_contacts(legs)

    # This pose is unstable, The hexapod has no balance
    if trio is None:
        return [], None, None

    p0, p1, p2 = get_corresponding_ground_contacts(trio, legs)
    n = get_normal_given_three_points(p0, p1, p2)

    # Note: using p0, p1 or p2 should yield the same result
    # height from cog to ground
    height = -dot(n, p0)

    # Get all contacts of the same height
    legs_on_ground = []

    for leg in legs:
        _height = -dot(n, leg.ground_contact())
        if isclose(height, _height, abs_tol=tol):
            legs_on_ground.append(leg)

    return legs_on_ground, n, height
def three_ids_of_ground_contacts(legs, tol=1):
    """
    Return three legs forming a stable position from legs,
    or None if no three legs satisfy this requirement.

    This function takes the legs of the hexapod
    and finds three legs on the ground that form a stable position
    returns the leg ids of those three legs
    return None if no stable position found
    """
    trios = set_of_trios_from_six()
    ground_contacts = [leg.ground_contact() for leg in legs]

    # (2, 3, 5) is a trio from the set [0, 1, 2, 3, 4, 5]
    # the corresponding other_trio of (2, 3, 5) is (0, 1, 4)
    # order is not important ie (2, 3, 5) is the same as (5, 3, 2)
    for trio, other_trio in zip(trios, reversed(trios)):
        p0, p1, p2 = [ground_contacts[i] for i in trio]

        if not check_stability(p0, p1, p2):
            continue

        # Get the vector normal to plane defined by these points
        # ❗IMPORTANT: The normal is always pointing up
        # because of how we specified the order of the trio
        # (and the legs in general)
        # starting from middle-right (id:0) to right back (id:5)
        # always towards one direction (ccw)
        n = get_normal_given_three_points(p0, p1, p2)

        # p0 is vector from cog (0, 0, 0) to ground contact
        # dot product of this and normal we get the
        # hypothetical (negative) height of ground contact to cog
        #
        #  cog *  ^ (normal_vector) ----
        #      \  |                  |
        #       \ |               -height
        #        \|                  |
        #         V p0 (foot_tip) ------
        #
        # using p0, p1 or p2 should yield the same result
        height = -dot(n, p0)

        # height should be the most largest since
        # the plane defined by this trio is on the ground
        # the other legs ground contact cannot be lower than the ground
        condition_violated = False
        for i in other_trio:
            _height = -dot(n, ground_contacts[i])
            if _height > height + tol:
                # Wrong leg combination, check another
                condition_violated = True
                break

        if not condition_violated:
            return trio  # Found one!

    # Nothing met the condition
    return None
Exemplo n.º 3
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def find_legs_on_ground(legs, n, height, tol=1):
    legs_on_ground = []
    for leg in legs:
        for point in reversed(leg.all_points[1:]):
            _height = -dot(n, point)
            if isclose(height, _height, abs_tol=tol):
                legs_on_ground.append(leg)
                break

    return legs_on_ground
def find_ground_plane_properties(legs):
    """
    Return three legs forming a stable position from legs,
    or None if no three legs satisfy this requirement.
    It also returns the normal vector of the plane
    defined by the three ground contacts, and the
    computed distance of the hexapod body to the ground plane
    """
    ground_contacts = [leg.ground_contact() for leg in legs]

    # (2, 3, 5) is a trio from the set [0, 1, 2, 3, 4, 5]
    # the corresponding other_trio of (2, 3, 5) is (0, 1, 4)
    # order is not important ie (2, 3, 5) is the same as (5, 3, 2)
    for trio in LEG_TRIOS:
        p0, p1, p2 = [ground_contacts[i] for i in trio]

        if not is_stable(p0, p1, p2):
            continue

        # Get the vector normal to plane defined by these points
        # ❗IMPORTANT: The normal is always pointing up
        # because of how we specified the order of the trio
        # (and the legs in general)
        # starting from middle-right (id:0) to right back (id:5)
        # always towards one direction (ccw)
        n = get_normal_given_three_points(p0, p1, p2)

        # p0 is vector from cog (0, 0, 0) to ground contact
        # dot product of this and normal we get the
        # hypothetical (negative) height of ground contact to cog
        #
        #  cog *  ^ (normal_vector) ----
        #      \  |                  |
        #       \ |               -height
        #        \|                  |
        #         V p0 (foot_tip) ------
        #
        # using p0, p1 or p2 should yield the same result
        height = -dot(n, p0)

        # height should be the highest since
        # the plane defined by this trio is on the ground
        # the other legs ground contact cannot be lower than the ground
        other_trio = [i for i in range(6) if i not in trio]
        other_points = [ground_contacts[i] for i in other_trio]
        if no_other_legs_lower(n, height, other_points):
            # Found one!
            return n, height

    # Nothing met the condition
    return None, None
Exemplo n.º 5
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def is_stable(p1, p2, p3, tol=0.001):
    """
    Determines stability of the pose.
    Determine if projection of 3D point p
    onto the plane defined by p1, p2, p3
    is within a triangle defined by p1, p2, p3.
    """
    p = Vector(0, 0, 0)
    u = vector_from_to(p1, p2)
    v = vector_from_to(p1, p3)
    n = cross(u, v)
    w = vector_from_to(p1, p)
    n2 = dot(n, n)
    beta = dot(cross(u, w), n) / n2
    gamma = dot(cross(w, v), n) / n2
    alpha = 1 - gamma - beta
    # then coordinate of the projected point (p_) of point p
    # p_ = alpha * p1 + beta * p2 + gamma * p3
    min_val = -tol
    max_val = 1 + tol
    cond1 = min_val <= alpha <= max_val
    cond2 = min_val <= beta <= max_val
    cond3 = min_val <= gamma <= max_val
    return cond1 and cond2 and cond3
Exemplo n.º 6
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def compute_orientation_properties(legs):
    """
    Returns:
      - Which legs are on the ground
      - Normal vector of the plane defined by these legs
      - Distance of this plane to center of gravity
    """
    # prefer leg combinations where legs are not adjacent to each other
    # introduce some randomness so we are not bias in
    # choosing one stable position over another
    shuffled_some_leg_trios = random.sample(SOME_LEG_TRIOS, len(SOME_LEG_TRIOS))
    leg_trios = shuffled_some_leg_trios + ADJACENT_LEG_TRIOS

    for leg_trio in leg_trios:

        other_leg_trio = [i for i in range(6) if i not in leg_trio]
        other_three_legs = [legs[i] for i in other_leg_trio]
        three_legs = [legs[i] for i in leg_trio]

        for joint_trio in JOINT_TRIOS:

            p0, p1, p2 = [legs[i].get_point(j) for i, j in zip(leg_trio, joint_trio)]

            if not is_stable(p0, p1, p2):
                continue

            n = get_normal_given_three_points(p0, p1, p2)
            height = -dot(n, p0)

            if same_leg_joints_break_condition(three_legs, joint_trio, n, height):
                continue

            if other_leg_joints_break_condition(other_three_legs, n, height):
                continue

            legs_on_ground = find_legs_on_ground(legs, n, height)
            return legs_on_ground, n, height

    return [], None, None
Exemplo n.º 7
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def is_lower(point, height, n, tol=1):
    _height = -dot(n, point)
    return _height > height + tol