Exemplo n.º 1
0
    def __init__(self):
        self.math = Math()
        self.q = [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.]
        self.comPositionBF = [0., 0.,
                              0.]  #var used only for IK inside constraints.py
        self.comPositionWF = [0., 0., 0.]
        self.footPosWLF = [0.3, 0.2, -.0]
        self.footPosWRF = [0.3, -0.2, -.0]
        self.footPosWLH = [-0.3, 0.2, -.0]
        self.footPosWRH = [-0.3, -0.2, -.0]
        self.externalForceWF = [0., 0., 0.]

        self.roll = 0.0
        self.pitch = 0.0
        self.yaw = 0.0

        self.LF_tau_lim = [50.0, 50.0, 50.0]
        self.RF_tau_lim = [50.0, 50.0, 50.0]
        self.LH_tau_lim = [50.0, 50.0, 50.0]
        self.RH_tau_lim = [50.0, 50.0, 50.0]
        self.torque_limits = np.array([
            self.LF_tau_lim, self.RF_tau_lim, self.LH_tau_lim, self.RH_tau_lim
        ])

        self.state_machineLF = True
        self.state_machineRF = True
        self.state_machineLH = True
        self.state_machineRH = True
        self.stanceFeet = [0, 0, 0, 0]
        self.numberOfContacts = 0
        #        self.contactsHF = np.zeros((4,3))
        self.contactsBF = np.zeros((4, 3))
        self.contactsWF = np.zeros((4, 3))

        axisZ = np.array([[0.0], [0.0], [1.0]])
        n1 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n2 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n3 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n4 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        # %% Cell 2
        self.normals = np.vstack([n1, n2, n3, n4])
        self.constraintMode = [
            'FRICTION_AND_ACTUATION', 'FRICTION_AND_ACTUATION',
            'FRICTION_AND_ACTUATION', 'FRICTION_AND_ACTUATION'
        ]

        self.friction = 0.8
        self.robotMass = 85  #Kg
        self.numberOfGenerators = 4

        self.actual_swing = 0
Exemplo n.º 2
0
def talker():

    gridmap = GridMap()
    math = Math()
    p = HyQSim()
    p.start()
    p.register_node()
    name = "Actuation_region"
    point = Point()
    polygonVertex = Point()
    actPolygon = Polygon3D()
    converter = gridMapConverter()
    i = 0

    for j in range(0, 50):
        vertices1 = [point]
        actPolygons = [polygonVertex]
        #        poly = []
        #        print("Time: " + str(i*0.004) + "s and Simulation time: " + str(p.get_sim_time()/60))
        p.get_sim_wbs()
        converter.getParamsFromRosDebugTopic(p.hyq_rcf_debug)
        trunk_mass = 85.
        mu = 0.8
        ng = 4
        axisZ = np.array([[0.0], [0.0], [1.0]])
        ''' normals '''
        n1 = np.transpose(
            np.transpose(math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n2 = np.transpose(
            np.transpose(math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n3 = np.transpose(
            np.transpose(math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n4 = np.transpose(
            np.transpose(math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        normals = np.vstack([n1, n2, n3, n4])

        print 'contacts: ', 1

        time.sleep(1.0 / 25.0)
        i += 1

    print 'de registering...'
    p.deregister_node()
Exemplo n.º 3
0
def computeVirtualImpedanceWrench(conf, act_pose, act_twist, W_contacts,
                                  des_pose, des_twist, des_acc, stance_legs,
                                  W_base_to_com, isCoMControlled, GravityComp,
                                  ffwdOn):
    util = Utils()
    # The inertia matrix (for simplicity we will use the same for com and base frame)
    B_Inertia = np.array(
        [[conf.robotInertia.Ixx, conf.robotInertia.Ixy, conf.robotInertia.Ixz],
         [conf.robotInertia.Ixy, conf.robotInertia.Iyy, conf.robotInertia.Iyz],
         [conf.robotInertia.Ixz, conf.robotInertia.Iyz,
          conf.robotInertia.Izz]])
    # Load math functions
    mathJet = Math()

    # Feedback wrench (Virtual PD)
    Kp_lin = np.diag([conf.Kp_lin_x, conf.Kp_lin_y, conf.Kp_lin_z])
    Kd_lin = np.diag([conf.Kd_lin_x, conf.Kd_lin_y, conf.Kd_lin_z])
    Kp_ang = np.diag([conf.KpRoll, conf.KpPitch, conf.KpYaw])
    Kd_ang = np.diag([conf.KdRoll, conf.KdPitch, conf.KdYaw])

    Wfbk = np.zeros(6)

    # linear part
    Wfbk[util.sp_crd["LX"]:util.sp_crd["LX"] +
         3] = Kp_lin.dot(util.linPart(des_pose) -
                         util.linPart(act_pose)) + Kd_lin.dot(
                             util.linPart(des_twist) - util.linPart(act_twist))
    # angular part
    # actual orientation
    b_R_w = mathJet.rpyToRot(util.angPart(act_pose))

    # Desired Orientation
    Rdes = mathJet.rpyToRot(util.angPart(des_pose))
    # compute orientation error
    Re = Rdes.dot(b_R_w.transpose())
    # express orientation error in angle-axis form
    err = rotMatToRotVec(Re)

    #the orient error is expressed in the base_frame so it should be rotated wo have the wrench in the world frame
    w_err = b_R_w.transpose().dot(err)
    # map des euler tates into des omega
    Jomega = mathJet.Tomega(util.angPart(act_pose))

    # Note we defined the angular part of the des twist as euler rates not as omega so we need to map them to an Euclidean space with Jomega
    Wfbk[util.sp_crd["AX"]:util.sp_crd["AX"] +
         3] = Kp_ang.dot(w_err) + Kd_ang.dot(
             Jomega.dot((util.angPart(des_twist) - util.angPart(act_twist))))

    #EXERCISE 3: Compute graviy wrench
    Wg = np.zeros(6)
    if (GravityComp):
        mg = conf.robotMass * np.array([0, 0, conf.gravity])
        Wg[util.sp_crd["LX"]:util.sp_crd["LX"] + 3] = mg
        #in case you are closing the loop on base frame
        if (not isCoMControlled):
            Wg[util.sp_crd["AX"]:util.sp_crd["AX"] + 3] = np.cross(
                W_base_to_com, mg)

    # EXERCISE 4: Feed-forward wrench
    Wffwd = np.zeros(6)
    if (ffwdOn):
        ffdLinear = conf.robotMass * util.linPart(des_acc)
        # compute inertia in the WF  w_I = R' * B_I * R
        W_Inertia = np.dot(b_R_w.transpose(), np.dot(B_Inertia, b_R_w))
        # compute w_des_omega_dot  Jomega*des euler_rates_dot + Jomega_dot*des euler_rates
        Jomega_dot = mathJet.Tomega_dot(util.angPart(des_pose),
                                        util.angPart(des_twist))
        w_des_omega_dot = Jomega.dot(util.angPart(des_acc)) + Jomega_dot.dot(
            util.angPart(des_twist))
        ffdAngular = W_Inertia.dot(w_des_omega_dot)
        #ffdAngular = W_Inertia.dot(util.angPart(des_acc))
        Wffwd = np.hstack([ffdLinear, ffdAngular])

    return Wffwd, Wfbk, Wg
Exemplo n.º 4
0
# number of decision variables of the problem
n = nc * 6

# contact positions
""" contact points """
LF_foot = np.array([0.3, 0.2, -.5])
print LF_foot
RF_foot = np.array([0.3, -0.2, -.5])
LH_foot = np.array([-0.3, 0.2, -.5])
RH_foot = np.array([-0.3, -0.2, -.5])
contacts = np.vstack((LF_foot, RF_foot, LH_foot, RH_foot))
''' parameters to be tuned'''
g = 9.81
mass = 100.
mu = 1.

n1 = array([0.0, 0.0, 1.0])
n2 = array([0.0, 0.0, 1.0])
n3 = array([0.0, 0.0, 1.0])
math = Math()
n1, n2, n3 = (math.normalize(n) for n in [n1, n2, n3])
normals = np.vstack([n1, n2, n3])

comp_dyn = ComputationalDynamics()
comp_dyn.iterative_projection_bretl(constraint_mode, contacts, normals, mass,
                                    ng, mu)

print("--- %s seconds ---" % (time.time() - start_time))

# pypoman.plot_polygon(points)
Exemplo n.º 5
0
    A = np.hstack([A1, A2, A3, A4])
    print A

    return A


g = 9.81
grav = np.array([[0.], [0.], [-g * mass]])
""" contact points """
LF_foot = np.array([0.3, 0.2, -.5])
RF_foot = np.array([0.3, -0.2, -.5])
LH_foot = np.array([-0.3, 0.2, -.5])
RH_foot = np.array([-0.3, -0.2, -.5])
contacts = np.vstack((LF_foot, RF_foot, LH_foot, RH_foot))
""" normals of the surface in the contact points """
math = Math()
LF_normal = np.array([[0.0], [0.0], [1.0]])
RF_normal = np.array([[0.0], [0.0], [1.0]])
LH_normal = np.array([[0.0], [0.0], [1.0]])
RH_normal = np.array([[0.0], [0.0], [1.0]])
LF_normal, RF_normal, LH_normal, RH_normal = (
    math.normalize(n) for n in [LF_normal, RF_normal, LH_normal, RH_normal])
normals = np.hstack((LF_normal, RF_normal, LH_normal, RH_normal))

#p = matrix(np.ones((3*nc,1)))
#
#cons1 = np.zeros((0,0))
#h_vec1 = np.zeros((0,1))
#cons2 = np.zeros((0,0))
#h_vec2 = np.zeros((0,1))
#
Exemplo n.º 6
0
class IterativeProjectionParameters:
    def __init__(self):
        self.math = Math()
        self.q = [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.]
        self.comPositionBF = [0., 0.,
                              0.]  #var used only for IK inside constraints.py
        self.comPositionWF = [0., 0., 0.]
        self.footPosWLF = [0.3, 0.2, -.0]
        self.footPosWRF = [0.3, -0.2, -.0]
        self.footPosWLH = [-0.3, 0.2, -.0]
        self.footPosWRH = [-0.3, -0.2, -.0]
        self.externalForceWF = [0., 0., 0.]

        self.roll = 0.0
        self.pitch = 0.0
        self.yaw = 0.0

        self.LF_tau_lim = [50.0, 50.0, 50.0]
        self.RF_tau_lim = [50.0, 50.0, 50.0]
        self.LH_tau_lim = [50.0, 50.0, 50.0]
        self.RH_tau_lim = [50.0, 50.0, 50.0]
        self.torque_limits = np.array([
            self.LF_tau_lim, self.RF_tau_lim, self.LH_tau_lim, self.RH_tau_lim
        ])

        self.state_machineLF = True
        self.state_machineRF = True
        self.state_machineLH = True
        self.state_machineRH = True
        self.stanceFeet = [0, 0, 0, 0]
        self.numberOfContacts = 0
        #        self.contactsHF = np.zeros((4,3))
        self.contactsBF = np.zeros((4, 3))
        self.contactsWF = np.zeros((4, 3))

        axisZ = np.array([[0.0], [0.0], [1.0]])
        n1 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n2 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n3 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        n4 = np.transpose(
            np.transpose(self.math.rpyToRot(0.0, 0.0, 0.0)).dot(axisZ))
        # %% Cell 2
        self.normals = np.vstack([n1, n2, n3, n4])
        self.constraintMode = [
            'FRICTION_AND_ACTUATION', 'FRICTION_AND_ACTUATION',
            'FRICTION_AND_ACTUATION', 'FRICTION_AND_ACTUATION'
        ]

        self.friction = 0.8
        self.robotMass = 85  #Kg
        self.numberOfGenerators = 4

        self.actual_swing = 0

    def setContactsPosBF(self, contactsBF):
        self.contactsBF = contactsBF

    def setContactsPosWF(self, contactsWF):
        self.contactsWF = contactsWF

    def setCoMPosWF(self, comWF):
        self.comPositionWF = comWF

    def setTorqueLims(self, torqueLims):
        self.torque_limits = torqueLims

    def setActiveContacts(self, activeContacts):
        self.stanceFeet = activeContacts
        #print self.stanceFeet

    def setContactNormals(self, normals):
        self.normals = normals

    def setConstraintModes(self, constraintMode):
        self.constraintMode = constraintMode

    def setFrictionCoefficient(self, mu):
        self.friction = mu

    def setNumberOfFrictionConesEdges(self, ng):
        self.numberOfGenerators = ng

    def setTotalMass(self, mass):
        self.robotMass = mass

    def getContactsPosWF(self):
        return self.contactsWF

    def getContactsPosBF(self):  # used only for IK inside constraints.py
        return self.contactsBF

    def getCoMPosWF(self):
        return self.comPositionWF

    def getCoMPosBF(self):
        return self.comPositionBF

    def getTorqueLims(self):
        return self.torque_limits

    def getStanceFeet(self):
        return self.stanceFeet

    def getNormals(self):
        return self.normals

    def getOrientation(self):
        return self.roll, self.pitch, self.yaw

    def getConstraintModes(self):
        return self.constraintMode

    def getFrictionCoefficient(self):
        return self.friction

    def getNumberOfFrictionConesEdges(self):
        return self.numberOfGenerators

    def getTotalMass(self):
        return self.robotMass

    def getStanceIndex(self, stanceLegs):
        stanceIdx = []
        #        print 'stance', stanceLegs
        for iter in range(0, 4):
            if stanceLegs[iter] == 1:
                #                print 'new poly', stanceIndex, iter
                stanceIdx = np.hstack([stanceIdx, iter])
        return stanceIdx

    def getCurrentFeetPos(self, received_data):
        num_of_elements = np.size(received_data.data)
        for j in range(0, num_of_elements):
            if str(received_data.name[j]) == str("footPosDesLFx"):
                self.footPosWLF[0] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesLFy"):
                self.footPosWLF[1] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesLFz"):
                self.footPosWLF[2] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesRFx"):
                self.footPosWRF[0] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesRFy"):
                self.footPosWRF[1] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesRFz"):
                self.footPosWRF[2] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesLHx"):
                self.footPosWLH[0] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesLHy"):
                self.footPosWLH[1] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesLHz"):
                self.footPosWLH[2] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesRHx"):
                self.footPosWRH[0] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesRHy"):
                self.footPosWRH[1] = received_data.data[j]
            if str(received_data.name[j]) == str("footPosDesRHz"):
                self.footPosWRH[2] = received_data.data[j]

        self.contactsWF = np.array([
            self.footPosWLF, self.footPosWRF, self.footPosWLH, self.footPosWRH
        ])

    def getParamsFromRosDebugTopic(self, received_data):

        num_of_elements = np.size(received_data.data)
        # print 'number of elements: ', num_of_elements
        for j in range(0, num_of_elements):
            #            print j, received_data.name[j], str(received_data.name[j]), str("footPosLFx")
            if str(received_data.name[j]) == str("LF_HAAmaxVar"):
                self.LF_tau_lim[0] = received_data.data[j]
            if str(received_data.name[j]) == str("LF_HFEmaxVar"):
                self.LF_tau_lim[1] = received_data.data[j]
            if str(received_data.name[j]) == str("LF_KFEmaxVar"):
                self.LF_tau_lim[2] = received_data.data[j]
            if str(received_data.name[j]) == str("RF_HAAmaxVar"):
                self.RF_tau_lim[0] = received_data.data[j]
            if str(received_data.name[j]) == str("RF_HFEmaxVar"):
                self.RF_tau_lim[1] = received_data.data[j]
            if str(received_data.name[j]) == str("RF_KFEmaxVar"):
                self.RF_tau_lim[2] = received_data.data[j]
            if str(received_data.name[j]) == str("LH_HAAmaxVar"):
                self.LH_tau_lim[0] = received_data.data[j]
            if str(received_data.name[j]) == str("LH_HFEmaxVar"):
                self.LH_tau_lim[1] = received_data.data[j]
            if str(received_data.name[j]) == str("LH_KFEmaxVar"):
                self.LH_tau_lim[2] = received_data.data[j]
            if str(received_data.name[j]) == str("RH_HAAmaxVar"):
                self.RH_tau_lim[0] = received_data.data[j]
            if str(received_data.name[j]) == str("RH_HFEmaxVar"):
                self.RH_tau_lim[1] = received_data.data[j]
            if str(received_data.name[j]) == str("RH_KFEmaxVar"):
                self.RH_tau_lim[2] = received_data.data[j]

            self.torque_limits = np.array([
                self.LF_tau_lim,
                self.RF_tau_lim,
                self.LH_tau_lim,
                self.RH_tau_lim,
            ])

            # the inputs are all in the WF this way we can compute generic regions for generic contact sets and generic com position

            if str(received_data.name[j]) == str("contact_setWLFx"):
                self.footPosWLF[0] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWLFy"):
                self.footPosWLF[1] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWLFz"):
                self.footPosWLF[2] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWRFx"):
                self.footPosWRF[0] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWRFy"):
                self.footPosWRF[1] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWRFz"):
                self.footPosWRF[2] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWLHx"):
                self.footPosWLH[0] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWLHy"):
                self.footPosWLH[1] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWLHz"):
                self.footPosWLH[2] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWRHx"):
                self.footPosWRH[0] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWRHy"):
                self.footPosWRH[1] = received_data.data[j]
            if str(received_data.name[j]) == str("contact_setWRHz"):
                self.footPosWRH[2] = received_data.data[j]

            self.contactsWF = np.array([
                self.footPosWLF, self.footPosWRF, self.footPosWLH,
                self.footPosWRH
            ])
            #print self.contactsWF

            if str(received_data.name[j]) == str("actual_CoMX"):
                self.comPositionWF[0] = received_data.data[j]
            if str(received_data.name[j]) == str("actual_CoMY"):
                self.comPositionWF[1] = received_data.data[j]
            if str(received_data.name[j]) == str("actual_CoMZ"):
                self.comPositionWF[2] = received_data.data[j]

            if str(received_data.name[j]) == str("offCoMX"):
                self.comPositionBF[0] = received_data.data[j]
            if str(received_data.name[j]) == str("offCoMY"):
                self.comPositionBF[1] = received_data.data[j]
            if str(received_data.name[j]) == str("offCoMZ"):
                self.comPositionBF[2] = received_data.data[j]

            # external wrench
            if str(received_data.name[j]) == str("extPerturbForceX"):
                self.externalForceWF[0] = received_data.data[j]
            if str(received_data.name[j]) == str("extPerturbForceY"):
                self.externalForceWF[1] = received_data.data[j]
            if str(received_data.name[j]) == str("extPerturbForceZ"):
                self.externalForceWF[2] = received_data.data[j]

#            print 'ext force ',self.externalForceWF

#            print self.contactsWF

            if str(received_data.name[j]) == str("LF_HAA_th"):
                self.q[0] = received_data.data[j]
            if str(received_data.name[j]) == str("LF_HFE_th"):
                self.q[1] = received_data.data[j]
            if str(received_data.name[j]) == str("LF_KFE_th"):
                self.q[2] = received_data.data[j]
            if str(received_data.name[j]) == str("RF_HAA_th"):
                self.q[3] = received_data.data[j]
            if str(received_data.name[j]) == str("RF_HFE_th"):
                self.q[4] = received_data.data[j]
            if str(received_data.name[j]) == str("RF_KFE_th"):
                self.q[5] = received_data.data[j]
            if str(received_data.name[j]) == str("LH_HAA_th"):
                self.q[6] = received_data.data[j]
            if str(received_data.name[j]) == str("LH_HFE_th"):
                self.q[7] = received_data.data[j]
            if str(received_data.name[j]) == str("LH_KFE_th"):
                self.q[8] = received_data.data[j]
            if str(received_data.name[j]) == str("RH_HAA_th"):
                self.q[9] = received_data.data[j]
            if str(received_data.name[j]) == str("RH_HFE_th"):
                self.q[10] = received_data.data[j]
            if str(received_data.name[j]) == str("RH_KFE_th"):
                self.q[11] = received_data.data[j]

            #they are in WF
            if str(received_data.name[j]) == str("normalLFx"):
                self.normals[0, 0] = received_data.data[j]
            if str(received_data.name[j]) == str("normalLFy"):
                self.normals[0, 1] = received_data.data[j]
            if str(received_data.name[j]) == str("normalLFz"):
                self.normals[0, 2] = received_data.data[j]

            if str(received_data.name[j]) == str("normalRFx"):
                self.normals[1, 0] = received_data.data[j]
            if str(received_data.name[j]) == str("normalRFy"):
                self.normals[1, 1] = received_data.data[j]
            if str(received_data.name[j]) == str("normalRFz"):
                self.normals[1, 2] = received_data.data[j]

            if str(received_data.name[j]) == str("normalLHx"):
                self.normals[2, 0] = received_data.data[j]
            if str(received_data.name[j]) == str("normalLHy"):
                self.normals[2, 1] = received_data.data[j]
            if str(received_data.name[j]) == str("normalLHz"):
                self.normals[2, 2] = received_data.data[j]

            if str(received_data.name[j]) == str("normalRHx"):
                self.normals[3, 0] = received_data.data[j]
            if str(received_data.name[j]) == str("normalRHy"):
                self.normals[3, 1] = received_data.data[j]
            if str(received_data.name[j]) == str("normalRHz"):
                self.normals[3, 2] = received_data.data[j]

            #print 'normals',self.normals

            if str(received_data.name[j]) == str("robotMass"):
                self.robotMass = received_data.data[j]

            if str(received_data.name[j]) == str("muEstimate"):
                self.friction = received_data.data[j]

            if str(received_data.name[j]) == str("roll"):
                self.roll = received_data.data[j]
            if str(received_data.name[j]) == str("pitch"):
                self.pitch = received_data.data[j]
            if str(received_data.name[j]) == str("yaw"):
                self.yaw = received_data.data[j]

            if str(received_data.name[j]) == str("actual_swing"):
                self.actual_swing = int(received_data.data[j])

        self.robotMass -= self.externalForceWF[2] / 9.81

    def getFutureStanceFeetFlags(self, received_data):

        num_of_elements = np.size(received_data.data)
        for j in range(0, num_of_elements):
            if str(received_data.name[j]) == str("future_stance_LF"):
                #                print 'future lf',received_data.data[j]
                self.stanceFeet[0] = int(received_data.data[j])
            if str(received_data.name[j]) == str("future_stance_RF"):
                self.stanceFeet[1] = int(received_data.data[j])
            if str(received_data.name[j]) == str("future_stance_LH"):
                self.stanceFeet[2] = int(received_data.data[j])
            if str(received_data.name[j]) == str("future_stance_RH"):
                self.stanceFeet[3] = int(received_data.data[j])
        print 'stance feet ', self.stanceFeet
        self.numberOfContacts = np.sum(self.stanceFeet)

    def getCurrentStanceFeetFlags(self, received_data):

        num_of_elements = np.size(received_data.data)
        for j in range(0, num_of_elements):
            if str(received_data.name[j]) == str("state_machineLF"):
                self.state_machineLF = int(received_data.data[j])
            if str(received_data.name[j]) == str("state_machineRF"):
                self.state_machineRF = int(received_data.data[j])
            if str(received_data.name[j]) == str("state_machineLH"):
                self.state_machineLH = int(received_data.data[j])
            if str(received_data.name[j]) == str("state_machineRH"):
                self.state_machineRH = int(received_data.data[j])

            if self.state_machineLF < 4.0:
                self.stanceFeet[0] = 1
            else:
                self.stanceFeet[0] = 0

            if self.state_machineRF < 4.0:
                self.stanceFeet[1] = 1
            else:
                self.stanceFeet[1] = 0

            if self.state_machineLH < 4.0:
                self.stanceFeet[2] = 1
            else:
                self.stanceFeet[2] = 0

            if self.state_machineRH < 4.0:
                self.stanceFeet[3] = 1
            else:
                self.stanceFeet[3] = 0

        self.numberOfContacts = np.sum(self.stanceFeet)
Exemplo n.º 7
0
set1 = PolygonTriple()


polygon.clockwise_sort(polygon)
hs = iterativeProjection.compute_halfspaces(polygon)
#print hs

nc = 3

contactsToStack = np.vstack((LF_foot,RF_foot,LH_foot,RH_foot))
contacts = contactsToStack[0:nc, :]

axisZ= np.array([[0.0], [0.0], [1.0]])

math = Math()
n1 = np.transpose(np.transpose(math.rpyToRot(1.5,1.5,0.0)).dot(axisZ))
n2 = np.transpose(np.transpose(math.rpyToRot(0.0,0.0,0.0)).dot(axisZ))
n3 = np.transpose(np.transpose(math.rpyToRot(0.0,0.0,0.0)).dot(axisZ))
n4 = np.transpose(np.transpose(math.rpyToRot(0.0,0.0,0.0)).dot(axisZ))
normals = np.vstack([n1, n2, n3, n4])


''' initialize Y_inner and Y_outer '''
inner_vx, directions = iterativeProjection.initiliaze_inner_appriximation(constraint_mode, mass, nc, contacts, com, normals)
outer_vx = iterativeProjection.initiliaze_outer_appriximation(inner_vx, directions)
'''1) Compute the edges of Y inner'''

'''2) Pick the edge cutting off the greatest fraction  of Y outer '''

'''3) Find the point in Y furthest outside this edge '''
Exemplo n.º 8
0
    def project(self, params):
        start_t = time.time()
        contacts = params.getContactsPosWF()
        contactsNumber = np.size(contacts,0)
        r1 = contacts[0,:]
        r2 = contacts[1,:]
        r3 = contacts[2,:]        
        g = 9.81
        mg = params.getTotalMass()*g
        normals = params.setContactNormals()
        n1 = normals[0,:]
        n2 = normals[1,:]
        n3 = normals[2,:]
        math_lp = Math()
        constr = Constraints()
        
        if constraint_mode == 'ONLY_ACTUATION':
            tau_HAA = 80
            tau_HFE = 120
            tau_KFE = 120
            dx = tau_HAA
            dy = tau_HFE
            dz = tau_KFE
            vertices_cl = np.array([[dx, dx, -dx, -dx, dx, dx, -dx, -dx],
                                 [dy, -dy, -dy, dy, dy, -dy, -dy, dy],
                                 [dz, dz, dz, dz, -dz, -dz, -dz, -dz]])
            kin = HyQKinematics()
            foot_vel = np.array([[0, 0, 0],[0, 0, 0],[0, 0, 0],[0, 0, 0]])
            contactsFourLegs = np.vstack([contacts, np.zeros((4-contactsNumber,3))])
            q, q_dot, J_LF, J_RF, J_LH, J_RH,isOutOfWorkspace = kin.inverse_kin(np.transpose(contactsFourLegs[:,0]),
                                                    np.transpose(foot_vel[:,0]),
                                                    np.transpose(contactsFourLegs[:,1]),
                                                    np.transpose(foot_vel[:,1]),
                                                    np.transpose(contactsFourLegs[:,2]),
                                                    np.transpose(foot_vel[:,2]))
            J_LF, J_RF, J_LH, J_RH = kin.update_jacobians(q)
            vertices_1 = np.transpose(constr.computeActuationPolygon(J_LF))
            vertices_2 = np.transpose(constr.computeActuationPolygon(J_RF))
            vertices_3 = np.transpose(constr.computeActuationPolygon(J_LH))
            #print vertices_1
            #print vertices_2
            #print vertices_3
            
        elif constraint_mode == 'ONLY_FRICTION':
        
            n1, n2, n3 = (math_lp.normalize(n) for n in [n1, n2, n3])
            R1, R2, R3 = (math_lp.rotation_matrix_from_normal(n) for n in [n1, n2, n3])
            # Inequality matrix for a contact force in local contact frame:
            #constr = Constraints()
            #C_force = constr.linearized_cone_local_frame(ng, mu)
            vertices_cl = constr.linearized_cone_vertices(ng, mu, mg)
            #vertices_cl = np.array([[0., dx, dx, -dx, -dx],
            #                     [0., dy, -dy, -dy, dy],
            #                     [0., dz, dz, dz, dz]])
            vertices_1 = np.dot(vertices_cl, R1.T)
            vertices_2 = np.dot(vertices_cl, R2.T)
            vertices_3 = np.dot(vertices_cl, R3.T)
            #vertices_1 = vertices_cl
            #vertices_2 = vertices_cl
            #vertices_3 = vertices_cl

        
        vertices_1 = np.transpose(vertices_1)
        vertices_2 = np.transpose(vertices_2)
        vertices_3 = np.transpose(vertices_3)

        tau1 = np.zeros((3,np.size(vertices_1,1)))
        tau2 = np.zeros((3,np.size(vertices_2,1)))
        tau3 = np.zeros((3,np.size(vertices_3,1)))     
        #print tau1        
        for j in range(0,np.size(vertices_cl,1)):
            tau1[:,j] = np.cross(r1, vertices_1[:,j])
            tau2[:,j] = np.cross(r2, vertices_2[:,j])
            tau3[:,j] = np.cross(r3, vertices_3[:,j])
        w1 = np.vstack([tau1, vertices_1])
        w2 = np.vstack([tau2, vertices_2])
        w3 = np.vstack([tau3, vertices_3]) #6XN
        print w1, w2, w3
        w12 = self.minksum(w1, w2)
        w123 = self.minksum(w12, w3) #CWC con punti interni 6XN
        
        
        #print 'number of vertex before convex hull', np.size(w123,1)
        w123_hull = self.convex_hull(w123) #this speeds up significantly!
        #print 'number of vertex after convex hull', np.size(w123_hull,1)
     
        #compute edges and slice them with mg
        pointsfZ, points_num = self.compute_section_points(w123_hull, np.array([0,0,0,0,0,1]), np.array([0,0,0,0,0,mg]))       
        #to avoid that convex hull complains because they are complanar remove the fz dimension
        pointsfZhull = self.convex_hull(pointsfZ[0:5,:])        
        
        pointsfY, points_num = self.compute_section_points(pointsfZhull, np.array([0,0,0,0,1]), np.array([0,0,0,0,0])) 
        #to avoid that convex hull complains because they are complanar remove the fz dimension        
        pointsfYhull = self.convex_hull(pointsfY[0:4,:])        
        
        
        pointsfX, points_num = self.compute_section_points(pointsfYhull, np.array([0,0,0,1]), np.array([0,0,0,0])) 
        #to avoid that convex hull complains because they are complanar remove the fz dimension        
        pointsfXhull = self.convex_hull(pointsfX[0:3,:])        

        pointstZ, points_num = self.compute_section_points(pointsfXhull, np.array([0,0,1]), np.array([0,0,0])) 
        #to avoid that convex hull complains because they are complanar remove the fz dimension        
        pointstZhull = self.convex_hull(pointstZ[0:2,:])          
#        pointsfX, points_num = self.compute_section_points(pointsfZhull, np.array([0,0,0,1,0,0]), np.array([0,0,0,0,0,0])) 
        
       
        #pointstZ, points_num = self.compute_section_points(pointsfY, np.array([0,0,1,0,0,0]), np.array([0,0,0,0,0,0])) 
        
            
        
        print np.size(w123_hull,1) 
        print "pointsfZ"        
        print np.size(pointsfZ,1)      
        print np.size(pointsfZhull,1) 
        
        print "pointsfy"
        print np.size(pointsfY,1)
        print np.size(pointsfYhull,1) #
        print "pointsfx"
        print np.size(pointsfX,1)
        print np.size(pointsfXhull,1) #
        print "pointstZx"
        print np.size(pointstZ,1)
        print np.size(pointstZhull,1) #
        
        print pointstZhull
#        points, points_num = self.compute_section_points(w123_hull, mg) 
#        
        # TODO: use pointsfZhull instead for "ONLY_FRICTION" option:
        #points2d = self.project_points(pointsfZhull, mg) #cimpute com points
        if constraint_mode == 'ONLY_ACTUATION':
            points2d = self.project_points(pointstZhull, mg) #cimpute com points
        elif constraint_mode == 'ONLY_FRICTION':
            points2d = self.project_points(pointsfZhull, mg) #cimpute com points
        
        #print points
        vertices2d = np.transpose(points2d)
        chull = scipy.spatial.ConvexHull(vertices2d)
        #print chull.vertices[0]
        print("Closed form algorith: --- %s seconds ---" % (time.time() - start_t))
        
        return vertices2d, chull.simplices