Ejemplo n.º 1
0
def select_contact_to_make(x_com, dx_com, robot, name_contact_to_break, contacts, contact_candidates, mu, gravity, mass, viewer=None, verb=0):
    (p, N) = compute_contact_points_from_contact_dictionary(robot, contacts);
    stabilityCriterion = StabilityCriterion("Stab_crit", x_com, dx_com, p.T, N.T, mu, gravity, mass, verb=verb);
    c_pred = mat_zeros((3,len(contact_candidates)));
    dc_pred = mat_zeros((3,len(contact_candidates)));
    v_pred = mat_zeros(len(contact_candidates));
    t_pred = mat_zeros(len(contact_candidates));
    
    # compute contact points for all contacts except the one to move
    contacts_minus_one = dict(contacts);
    del contacts_minus_one[name_contact_to_break];
    (P_minus_one, N_minus_one) = compute_contact_points_from_contact_dictionary(robot, contacts_minus_one);
    i = P_minus_one.shape[1];
    p[:,:i] = P_minus_one;
    N[:,:i] = N_minus_one;

    c_id=0;
    P_cand = np.matrix(contacts[name_contact_to_break]['P']).T;  # contact points of contact to break in local frame
    N_cand = np.matrix(contacts[name_contact_to_break]['N']).T;  # contact normals of contact to break in local frame
    for (c_id,oMi) in enumerate(contact_candidates):
        # compute new position of contact points
        for j in range(P_cand.shape[1]):
            p[:,i+j] = oMi.act(P_cand[:,j]);
            N[:,i+j] = oMi.rotation * N_cand[:,j]; 

        if(verb>0 and viewer is not None):
            # update contact points in viewer
            for j in range(p.shape[1]):
                viewer.addSphere("contact_point"+str(j), 0.005, p[:,j], (0.,0.,0.), (1, 1, 1, 1));
                viewer.updateObjectConfigRpy("contact_point"+str(j), p[:,j]);

        # check whether the system can stop with this contacts
        stabilityCriterion.set_contacts(p.T, N.T, mu);
        try:
            stab_res = stabilityCriterion.can_I_stop(x_com, dx_com);
            c_pred[:,c_id] = np.asmatrix(stab_res.c).T;
            dc_pred[:,c_id] = np.asmatrix(stab_res.dc).T;
            v_pred[c_id] = norm(stab_res.dc);
            t_pred[c_id] = stab_res.t;
            if(verb>0):
                print "[select_contact_to_make] Candidate %d, predicted com vel in %.3f s = %.3f"%(c_id, stab_res.t, norm(stab_res.dc));
#                raw_input();
        except Exception as e:
            print "ERROR while computing stability criterion:", e;
        
    best_candidate_ids = np.where(abs(v_pred-np.min(v_pred))<EPS)[0];
    if(best_candidate_ids.shape[0]>1):
        # if multiple contacts result in the same final com velocity (typically that would be 0), 
        # pick the one who does it faster
        best_candidate_id = best_candidate_ids[np.argmin(t_pred[best_candidate_ids])];
    else:
        best_candidate_id = best_candidate_ids[0];

    return Bunch(index=best_candidate_id, c=c_pred[:,best_candidate_id], 
                 dc=dc_pred[:,best_candidate_id], t=t_pred[best_candidate_id,0]);
Ejemplo n.º 2
0
def predict_future_com_state(x_com, dx_com, robot, mass, contacts, mu, gravity, time, verb=0):
    ''' Predict future com state
    '''
    (P,N) = compute_contact_points_from_contact_dictionary(robot, contacts);
    stabilityCriterion = StabilityCriterion("Stab_crit", x_com, dx_com, P.T, N.T, mu, gravity, mass, verb=verb);
    try:
        res = stabilityCriterion.predict_future_state(time);
        if(verb>0):
            print "[predict_future_com_state] Contacts can be kept for %.3f s"%(res.t);
            print "                           Predicted com state = (", res.c.T, res.dc.T, "), norm(dc)=%.3f"%norm(res.dc);
    except Exception as e:
        print "ERROR while computing stability criterion predict_future_state:", e;
    return res;
Ejemplo n.º 3
0
def select_contact_to_break(x_com, dx_com, robot, mass, contacts, mu, gravity, step_time, verb=0):
    ''' Select which contact to break
    '''
    p   = mat_zeros((3,1));
    N   = mat_zeros((3,1));
    N[2,:] = 1.0;
    stabilityCriterion = StabilityCriterion("Stab_crit", x_com, dx_com, p.T, N.T, mu, gravity, mass, verb=verb);
    t_pred  = mat_zeros(len(contacts));
    t_min  = mat_zeros(len(contacts));
    v_pred  = mat_zeros(len(contacts));
    c_pred  = mat_zeros((3,len(contacts)));
    dc_pred = mat_zeros((3,len(contacts)));
    dc_min = mat_zeros((3,len(contacts)));
    for (contactId, name_of_contact_to_break) in enumerate(contacts):
        # compute the contact points without name_of_contact_to_break
        contacts_minus_one = dict(contacts);
        del contacts_minus_one[name_of_contact_to_break];
        (p,N) = compute_contact_points_from_contact_dictionary(robot, contacts_minus_one);
        
        # predict future com state supposing to break name_of_contact_to_break
        stabilityCriterion.set_contacts(p.T, N.T, mu);
        try:
            res = stabilityCriterion.predict_future_state(step_time);
            t_pred[contactId] = res.t;
            t_min[contactId] = res.t_min;
            c_pred[:,contactId] = np.asmatrix(res.c).T;
            dc_pred[:,contactId] = np.asmatrix(res.dc).T;
            dc_min[:,contactId] = np.asmatrix(res.dc_min).T;
            v_pred[contactId] = norm(res.dc);
            if(verb>0):
                print "[select_contact_to_break] Without contact %s contacts can be kept for %.3f s"%(name_of_contact_to_break,res.t);
                print "                          Predicted com state = (", res.c.T, res.dc.T, "), norm(dc)=%.3f"%norm(res.dc);
        except Exception as e:
            print "ERROR while computing stability criterion:", e;
    
    t_pred_sorted = sorted(t_pred.A.squeeze());
    if(t_pred_sorted[-1] > t_pred_sorted[-2]+EPS):
        id_contact_to_break = np.argmax(t_pred);
    else:
        id_contact_to_break = np.argmin(v_pred);
    name_of_contact_to_break = contacts.keys()[id_contact_to_break];
    return Bunch(name=name_of_contact_to_break, c=c_pred[:,id_contact_to_break], 
                 dc=dc_pred[:,id_contact_to_break], t=t_pred[id_contact_to_break,0],
                 t_min=t_min[id_contact_to_break,0], dc_min=dc_min[:,id_contact_to_break]);
Ejemplo n.º 4
0
def com_pos_after_t(c, q_hpp, contacts, v = None, t = 0.7):
    q0 =  q_pin(q_hpp)
    init(q0);
    v0 = mat_zeros(nv);
    #~ invDynForm.setNewSensorData(0, q0, v0);
    #~ updateConstraints(0, q0, v0, invDynForm, contacts);
    #~ draw_q(q0);
    print 'Gonna compute initial joint velocities that satisfy contact constraints';
    print 'conf.MAX_INITIAL_COM_VEL', conf.MAX_INITIAL_COM_VEL
    if(v == None):
        (success, v) = compute_initial_joint_velocities_multi_contact(q0, robot, contacts, [True]*6, conf.mu[0], 
                                                    conf.ZERO_INITIAL_ANGULAR_MOMENTUM, 
                                                    conf.ZERO_INITIAL_VERTICAL_COM_VEL,
                                                    False, #conf.ENSURE_STABILITY, 
                                                    True, #conf.ENSURE_UNSTABILITY, 
                                                    conf.MAX_INITIAL_COM_VEL,conf.MAX_MIN_JOINT_ACC , 100);
    else:
        success = True
    if (not success):
        print "Could not find initial velocities"                       
        return (success, v[:], c, v0);
    
    c_init = np.matrix(c)
    dx_com_des = mat_zeros(3);
    #~ P = np.matlib.copy(invDynForm.contact_points);
    #~ N = np.matlib.copy(invDynForm.contact_normals);
    robot.computeAllTerms(q0, mat_zeros(nv));
    robot.framesKinematics(q0);
    (P,N) = compute_contact_points_from_contact_dictionary(robot, contacts)
    print "contacts ",  len(contacts)
    print "contacts ",  contacts
    print "normals ",  N    
    M = robot.mass(q0, update_kinematics=True);
    J_com   = robot.Jcom(q0, update_kinematics=False);
    print "Mas ", M
    stab_criterion = StabilityCriterion("default", np.matrix(c), dx_com_des, P.T, N.T, conf.mu[0], np.array([0,0,-9.81]), M[0,0]) 
    res = stab_criterion.predict_future_state(t, c_init, J_com * v)
    #TODO : res.t != 0.7
    print "c ", res.c
    print "dc ", res.dc
    return success and abs(res.t - t)< EPS , res.dc, res.c, v0
Ejemplo n.º 5
0
def compute_initial_joint_velocities_multi_contact(q, robot, contacts, constraint_mask, mu, 
                                                   ZERO_INITIAL_ANGULAR_MOMENTUM, 
                                                   ZERO_INITIAL_VERTICAL_COM_VEL,
                                                   ENSURE_STABILITY, ENSURE_UNSTABILITY, 
                                                   MAX_INITIAL_COM_VEL, MAX_MIN_JOINT_ACC, MAX_ITER):
    nv = robot.nv;
    na = robot.nv-6;
    
    robot.computeAllTerms(q, mat_zeros(nv));
    robot.framesKinematics(q);
    x_com   = robot.com(q, update_kinematics=False);
    J_com   = robot.Jcom(q, update_kinematics=False);
    M       = robot.mass(q, update_kinematics=False);
    constr_dim = constraint_mask.sum();
    k       = int(np.sum([constr_dim for con in contacts]));
    Jc      = mat_zeros((k,nv));
    i       = 0;
    for name in contacts:
        fid = robot.model.getFrameId(name);
        Jc[i:i+constr_dim,:] = robot.frameJacobian(q, fid, False);
        i += constr_dim;

    (P,N) = compute_contact_points_from_contact_dictionary(robot, contacts);
    n_in = k+3 if ZERO_INITIAL_ANGULAR_MOMENTUM else k;
    n_in +=  1 if ZERO_INITIAL_VERTICAL_COM_VEL else 0;
    A = J_com;
    A_in = mat_zeros((n_in,nv));
    lb_in = mat_zeros(n_in);
    ub_in = mat_zeros(n_in);
    A_in[:k,:] = Jc;
    if(ZERO_INITIAL_ANGULAR_MOMENTUM):
        A_in[k:k+3,:] = M[3:6,:];
    if(ZERO_INITIAL_VERTICAL_COM_VEL):
        A_in[-1,:] = J_com[2,:];
    # compute joint velocity bounds for viability
    v_lb = mat_zeros(nv)-1e10;
    v_ub = mat_zeros(nv)+1e10;
    qMin       = robot.model.lowerPositionLimit;
    qMax       = robot.model.upperPositionLimit;
    dqMax      = robot.model.velocityLimit;
    for j in range(na):
        (v_lb[6+j], v_ub[6+j]) = computeVelLimits(q[7+j], qMin[7+j], qMax[7+j], dqMax[6+j], MAX_MIN_JOINT_ACC);

    # verify that given CoM position allows for static equilibrium
    dx_com_des = mat_zeros(3);
    v0 = mat_zeros(3);
    stab_criterion = StabilityCriterion("default", x_com, dx_com_des, P.T, N.T, mu, np.array([0,0,-9.81]), M[0,0]);
    try:
        # check initial state is in static equilibrium
        res = stab_criterion.can_I_stop();
        if(not res.is_stable):
            print "[compute_initial_joint_velocities_multi_contact] ERROR: initial configuration is not in static equilibrium", res.c, res.dc;
            return (False, v0);
    except Exception as e:
        print "[compute_initial_joint_velocities_multi_contact] Error while testing static equilibrium. %s"%str(e);

    # sample desired CoM velocities
    initial_state_generated = False;
    counter = 0;        
    while(not initial_state_generated):
        counter += 1;        
        if(counter > MAX_ITER):
            return (False, v0);
        
        dx_com_des = MAX_INITIAL_COM_VEL * mat_rand(3) / sqrt(3.0);
        if(ENSURE_STABILITY or ENSURE_UNSTABILITY):
            try:
                res = stab_criterion.can_I_stop(x_com, dx_com_des);
                if((ENSURE_STABILITY and not res.is_stable) or (ENSURE_UNSTABILITY and res.is_stable)):
                    continue;
            except Exception as e:
                print "[compute_initial_joint_velocities_multi_contact] Error while checking stability of desired com velocity. %s"%str(e);
                continue;
        
        # solve QP to find joint velocities
        (imode,v0) = solveLeastSquare(A.A, dx_com_des.A, v_lb.A, v_ub.A, A_in.A, lb_in.A, ub_in.A, regularization=1e-4);
        if(imode==0):
            dx_com_0 = np.dot(J_com, v0);
            try:
                res = stab_criterion.can_I_stop(x_com, dx_com_0);
                if((ENSURE_UNSTABILITY and not res.is_stable) or (ENSURE_STABILITY and res.is_stable) or
                   (not ENSURE_STABILITY and not ENSURE_UNSTABILITY)):
                    initial_state_generated = True;
            except Exception as e:
                print "[compute_initial_joint_velocities_multi_contact] Error while checking stability of com velocity. %s"%str(e);
        
    return (True, v0);
Ejemplo n.º 6
0
def test_discretize_vs_discretize_momentum(N_CONTACTS=2,
                                           solver='qpoases',
                                           verb=0):

    DO_PLOTS = False
    PLOT_3D = False
    mu = 0.5
    # friction coefficient
    lx = 0.1
    # half foot size in x direction
    ly = 0.07
    # half foot size in y direction
    #First, generate a contact configuration
    CONTACT_POINT_UPPER_BOUNDS = [0.5, 0.5, 0.5]
    CONTACT_POINT_LOWER_BOUNDS = [-0.5, -0.5, 0.0]
    gamma = atan(mu)
    # half friction cone angle
    RPY_LOWER_BOUNDS = [-2 * gamma, -2 * gamma, -pi]
    RPY_UPPER_BOUNDS = [+2 * gamma, +2 * gamma, +pi]
    MIN_CONTACT_DISTANCE = 0.3
    global mass
    global g_vector
    X_MARG = 0.07
    Y_MARG = 0.07

    succeeded = False
    while (not succeeded):
        (p, N) = generate_contacts(N_CONTACTS, lx, ly, mu,
                                   CONTACT_POINT_LOWER_BOUNDS,
                                   CONTACT_POINT_UPPER_BOUNDS,
                                   RPY_LOWER_BOUNDS, RPY_UPPER_BOUNDS,
                                   MIN_CONTACT_DISTANCE, False)
        X_LB = np.min(p[:, 0] - X_MARG)
        X_UB = np.max(p[:, 0] + X_MARG)
        Y_LB = np.min(p[:, 1] - Y_MARG)
        Y_UB = np.max(p[:, 1] + Y_MARG)
        Z_LB = np.max(p[:, 2] + 0.3)
        Z_UB = np.max(p[:, 2] + 1.5)
        #~ (H,h) = compute_GIWC(p, N, mu, False);
        H = -compute_CWC(p, N, mass, mu)
        h = zeros(H.shape[0])
        (succeeded, c0) = find_static_equilibrium_com(mass, [X_LB, Y_LB, Z_LB],
                                                      [X_UB, Y_UB, Z_UB], H, h)

    dc0 = np.random.uniform(-1, 1, size=3)

    Z_MIN = np.max(p[:, 2]) - 0.1
    Ineq_kin = zeros([3, 3])
    Ineq_kin[2, 2] = -1
    ineq_kin = zeros(3)
    ineq_kin[2] = -Z_MIN

    #~
    bezierSolver = BezierZeroStepCapturability(
        "ss",
        c0,
        dc0,
        p,
        N,
        mu,
        g_vector,
        mass,
        verb=verb,
        solver=solver,
        kinematic_constraints=[Ineq_kin, ineq_kin])
    #~ bezierSolver = BezierZeroStepCapturability("ss", c0, dc0, p, N, mu, g_vector, mass, verb=verb, solver=solver, kinematic_constraints = None);
    stabilitySolver = StabilityCriterion("ss",
                                         c0,
                                         dc0,
                                         p,
                                         N,
                                         mu,
                                         g_vector,
                                         mass,
                                         verb=verb,
                                         solver=solver)
    window_times = [1] + [0.1 * i for i in range(1, 10)
                          ] + [0.1 * i
                               for i in range(11, 21)]  #try nominal time first
    #~ window_times =  [0.2*i for i in range(1,5)] + [0.2*i for i in range(6,11)] #try nominal time first
    #~ window_times = [1]+ [0.4*i for i in range(1,4)] #try nominal time first
    #~ window_times = [1]+ [0.4*i for i in range(3,6)] #try nominal time first
    window_times = [0.7]
    found = False
    time_step_check = 0.01
    for i, el in enumerate(window_times):
        if (found):
            break
        res = bezierSolver.can_I_stop(T=el, time_step=time_step_check)
        if (res.is_stable):
            found = True
            #~ print "continuous found at ", el
            __check_trajectory(bezierSolver._p0,
                               bezierSolver._p1,
                               res.c,
                               res.c,
                               el,
                               bezierSolver._H,
                               bezierSolver._mass,
                               bezierSolver._g,
                               time_step=time_step_check,
                               dL=bezier(
                                   matrix([p_i.tolist()
                                           for p_i in res.wpsdL]).transpose()))
            if i != 0:
                print "discretize Failed to stop at 1, but managed to stop at ", el

    found = False
    time_step_check = 0.01
    for i, el in enumerate(window_times):
        if (found):
            break
        res2 = bezierSolver.can_I_stop(T=el,
                                       time_step=time_step_check,
                                       l0=zeros(3))
        if (res2.is_stable):
            found = True
            #~ print "ang_momentum found at ", el
            __check_trajectory(
                bezierSolver._p0,
                bezierSolver._p1,
                res2.c,
                res2.c,
                el,
                bezierSolver._H,
                #~ bezierSolver._mass, bezierSolver._g, time_step = time_step_check, dL = res2.dL_of_t)
                bezierSolver._mass,
                bezierSolver._g,
                time_step=time_step_check,
                dL=bezier(
                    matrix([p_i.tolist() for p_i in res2.wpsdL]).transpose()))
            if i != 0:
                print "ang_momentum Failed to stop at 1, but managed to stop at ", el
    #~ res2 = None
    #~ try:
    #~ res2 = stabilitySolver.can_I_stop();
    #~ except Exception as e:
    #~ pass

    if (res2.is_stable != res.is_stable):
        if (res.is_stable):
            print "discretize won"
        else:
            print "ang_momentum won"

    return res2.is_stable, res.is_stable, res2, res, c0, dc0, H, h, p, N