def _update(self, t, t0=0, fig='on'): """Update function where we update the """ MAP = self.MAP_ t -= 1 # if t == t0: # self._build_first_map(t0,use_lidar_yaw=True) # return correlations = np.empty(self.num_p_) for i in range(self.num_p_): #0) Extract Params from LiDAR and Joints lidar_scan, lidar_ts = self.lidar_._get_scan(idx=t) neck_angle, head_angle, _ = self.joints_._get_head_angles( ts=lidar_ts) good_lidar_idxs = self.good_lidar_idx(lidar_scan) l_lidar_pts = self._polar_to_cart(lidar_scan, res_rad=self.lidar_.res_rad) l_lidar_pts = l_lidar_pts[:, good_lidar_idxs] homo_l_lidar_pts = np.ones((4, l_lidar_pts.shape[1]), dtype=np.float64) homo_l_lidar_pts[:3, :] = l_lidar_pts p_curr = self.particles_[:, i] # p_curr[2] = self.lidar_.data_[t]['rpy'][0, 2] #1) Transform LiDAR Scan to global world frame #a) lidar -> body R_bl = np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)) T_bl = np.array([0, 0, 0.15], dtype=np.float64) H_bl = tf.homo_transform(R_bl, T_bl) #b) body -> global (only considering yaw atm) R_gb = tf.rot_z_axis(p_curr[2]) T_gb = np.array([p_curr[0], p_curr[1], self.h_lidar_]) H_gb = tf.homo_transform(R_gb, T_gb) #c) apply to lidar_pts H_gl = H_gb @ H_bl g_lidar_pts = H_gl @ homo_l_lidar_pts #d) remove ground (all points with global y < 0.0) non_ground_idx = g_lidar_pts[2, :] > 0.0 g_lidar_pts = g_lidar_pts[:, non_ground_idx] #e) Convert to map cell coords & Compute corr(m_t, y_t) m_lidar_pts = (self.lidar_._physicPos2PosVec( MAP, g_lidar_pts[:2, :])).astype(np.int64) corr = prob.mapCorrelation(MAP['map'], m_lidar_pts) correlations[i] = corr self.weights_ = prob.update_weights(self.weights_, correlations) #Update the best particle position max_idx = np.argmax(self.weights_) g_particle = self.particles_[:, max_idx] self.best_p_[:, t + 1] = g_particle m_particle = self.lidar_._physicPos2Pos(MAP, g_particle[:2]).astype( np.int64) self.best_p_indices_[:, t + 1] = m_particle self.MAP_ = MAP return MAP
def buildMAP(self, t, x, y, theta): # MAP = self.MAP_ tj0 = self.getJointTime(t) scan = self.lidar_.data_[t]['scan'][0] neck_angle, head_angle = self.joints_.data_['head_angles'][:, tj0][ 0], self.joints_.data_['head_angles'][:, tj0][1] body_2_lidar_rot = tf.homo_transform( np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)), [0, 0, 0]) ground_2_body = tf.homo_transform(tf.rot_z_axis(theta), [x, y, self.h_lidar_]) #Got the transforms homoscan = np.empty((4, (self.lidar_angles).shape[1]), dtype=np.float) homoscan[0, :] = np.cos(self.lidar_angles) * scan homoscan[1, :] = np.sin(self.lidar_angles) * scan homoscan[2, :] = np.zeros((1, self.lidar_angles.shape[1])) homoscan[3, :] = np.ones(self.lidar_angles.shape[1]) # xscan = np.cos(self.lidar_angles)*scan # yscan = np.sin(self.lidar_angles)*scan # zscan = np.zeros((1,xscan.shape[1])) # Onescan = np.ones(zscan.shape) ground_2_lidar = np.dot(ground_2_body, body_2_lidar_rot) # homoscan = np.vstack((xscan,yscan,zscan,Onescan)) trans_scan = (np.dot(ground_2_lidar, homoscan)).astype(np.float16) ground_zz = trans_scan[2] < 0.1 x_new = ((trans_scan[0] - self.MAP_['xmin']) // self.MAP_['res']).astype(np.uint16) y_new = ((trans_scan[1] - self.MAP_['ymin']) // self.MAP_['res']).astype(np.uint16) x_start = ((x - self.MAP_['xmin']) // self.MAP_['res']).astype( np.uint16) y_start = ((y - self.MAP_['xmin']) // self.MAP_['res']).astype( np.uint16) if not (self.psx == x_start and self.psy == y_start): self.bresenDict = {} self.psx = x_start self.psy = y_start for x_n, y_n, ground in zip(x_new, y_new, ground_zz): if abs(x_n) < self.MAP_['sizex'] and abs(y_n) < self.MAP_['sizey']: if (self.bresenDict.get((x_n, y_n)) is None): ray_cells = bresenham2D(x_start, y_start, x_n, y_n) self.bresenDict[(x_n, y_n)] = ray_cells else: ray_cells = self.bresenDict[(x_n, y_n)] self.dict_use_count = self.dict_use_count + 1 # print("using dict") x = np.asarray(ray_cells[0], dtype=int) y = np.asarray(ray_cells[1], dtype=int) x_end = x[-1] y_end = y[-1] x = x[:-1] y = y[:-1] self.log_odds_[x, y] = self.log_odds_[x, y] + np.log( self.p_false_) self.MAP_['map'][x, y] = self.log_odds_[x, y] > np.log(1.5) self.log_odds_[x_end, y_end] = self.log_odds_[ x_end, y_end] + (1 - ground) * np.log(self.p_true_)
def ray_in_world(self,R_pose,head_angle, neck_angle,lidar_rays, theta): lidar_rays_x = lidar_rays * np.cos(theta) lidar_rays_y = lidar_rays * np.sin(theta) homo_lidar_to_head = np.array([[1,0,0,0],[0,1,0,0],[0,0,1,0.15],[0,0,0,1]]) homo_head_to_body = tf.homo_transform(np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)),np.array([0,0,0.33])) homo_body_to_ground = tf.homo_transform(tf.rot_z_axis(R_pose[2]) , np.array([R_pose[0],R_pose[1],0.93])) ray_ground = np.linalg.multi_dot([homo_body_to_ground , homo_head_to_body, homo_lidar_to_head, np.array( [lidar_rays_x, lidar_rays_y, np.zeros(lidar_rays_x.shape[0]), np.ones(lidar_rays_x.shape[0])] ) ]) #ray_ground = homo_body_to_ground @ homo_head_to_body @ homo_lidar_to_head @ np.array( [lidar_rays_x, lidar_rays_y, np.zeros(lidar_rays_x.shape[0]), np.ones(lidar_rays_x.shape[0])] ) return ray_ground[:,ray_ground[2,:] > 0.2]
def ray_in_world(self,R_pose,head_angle, neck_angle,lidar_rays, theta): homo_lidar_to_head = np.array([[1,0,0,0],[0,1,0,0],[0,0,1,0.15],[0,0,0,1]]) homo_head_to_body = tf.homo_transform(np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)),np.array([0,0,0.33])) homo_body_to_ground = tf.homo_transform(tf.rot_z_axis(R_pose[2]) , np.array([R_pose[0],R_pose[1],0.93])) homo_lidar_to_body = np.dot(homo_head_to_body , homo_lidar_to_head) homo_lidar_to_ground = np.dot(homo_body_to_ground,homo_lidar_to_body) #ray_angle = theta.reshape((1,theta.shape[0])) lidar_rays_x = lidar_rays * np.cos(theta)#(ray_angle) lidar_rays_y = lidar_rays * np.sin(theta)#(ray_angle) #lidar_rays_z = np.zeros((1,lidar_rays_x.shape[1])) #ones = np.ones((1,lidar_rays_x.shape[1])) ray_ground = np.dot( homo_lidar_to_ground , np.array( [lidar_rays_x, lidar_rays_y, np.zeros(lidar_rays_x.shape[0]), np.ones(lidar_rays_x.shape[0])] )) #np.vstack( (lidar_rays_x, lidar_rays_y, lidar_rays_z, ones) ) ) return ray_ground[:,ray_ground[2,:] > 0.1]
def _lidar_to_body_homo(self, head_angle, neck_angle): rot_neck = tf.rot_z_axis(neck_angle) # trans_neck = np.array([0,0,0]) neck_homo = tf.homo_transform(rot_neck, [0, 0, 0]) rot_head = tf.rot_y_axis(head_angle) # trans_head = np.array([0,0,0]) head_homo = tf.homo_transform(rot_head, [0, 0, 0]) body_to_head_homo = np.array([[1, 0, 0, 0], [0, 1, 0, 0], [0, 0, 1, 0.33], [0, 0, 0, 1]]) body_to_head = np.dot(np.dot(body_to_head_homo, neck_homo), head_homo) head_to_lidar_homo = np.array([[1, 0, 0, 0], [0, 1, 0, 0], [0, 0, 1, 0.15], [0, 0, 0, 1]]) lidar_to_body_homo = np.dot(body_to_head, head_to_lidar_homo) return lidar_to_body_homo
def _mapping(self, t=0, use_lidar_yaw=True): """Build the map """ t -= 1 # Extract a ray from lidar data MAP = self.MAP_ print('\n--------Building the map--------') #0) Extract Params from LiDAR and Joints lidar_scan, lidar_ts = self.lidar_._get_scan(idx=t) neck_angle, head_angle, _ = self.joints_._get_head_angles(ts=lidar_ts) good_lidar_idxs = self.good_lidar_idx(lidar_scan) l_lidar_pts = self._polar_to_cart(lidar_scan, res_rad=self.lidar_.res_rad) l_lidar_pts = l_lidar_pts[:, good_lidar_idxs] homo_l_lidar_pts = np.ones((4, l_lidar_pts.shape[1]), dtype=np.float64) homo_l_lidar_pts[:3, :] = l_lidar_pts if use_lidar_yaw: yaw = self.lidar_.data_[t]['rpy'][0, 2] t_gb_x, t_gb_y, _ = self.best_p_[:, t] else: t_gb_x, t_gb_y, yaw = self.best_p_[:, t] p_curr = np.array([t_gb_x, t_gb_y, yaw], dtype=np.float64) #1) Transform LiDAR Scan to global world frame #a) lidar -> body R_bl = np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)) T_bl = np.array([0, 0, 0.15], dtype=np.float64) H_bl = tf.homo_transform(R_bl, T_bl) #b) body -> global (only considering yaw atm) R_gb = tf.rot_z_axis(yaw) T_gb = np.array([t_gb_x, t_gb_y, self.h_lidar_]) H_gb = tf.homo_transform(R_gb, T_gb) #c) apply to lidar_pts H_gl = H_gb @ H_bl g_lidar_pts = H_gl @ homo_l_lidar_pts #d) remove ground (all points with global y < 0.0) non_ground_idx = g_lidar_pts[2, :] > 0.0 g_lidar_pts = g_lidar_pts[:, non_ground_idx] #e) Use bresenham2D to get free/occupied cell locations g_curr_pose = p_curr m_curr_pose = self.lidar_._physicPos2Pos(MAP, g_curr_pose[:2]) m_lidar_pts = self.lidar_._physicPos2PosVec(MAP, g_lidar_pts[:2, :]) for ray in range(g_lidar_pts.shape[1]): m_lidar_pt = m_lidar_pts[:, ray] ret = bresenham2D(m_curr_pose[0], m_curr_pose[1], m_lidar_pt[0], m_lidar_pt[1]).astype(int) free_coords = ret[:, :-1] occupied_coords = ret[:, -1] #f) Update Log Odds Map (increase all the free cells) log_pos = np.log(self.p_true_ / (1 - self.p_true_)) log_neg = np.log(self.p_false_ / (1 - self.p_false_)) self.log_odds_[tuple(occupied_coords)] += log_pos self.log_odds_[tuple(free_coords)] += log_neg MAP['map'][self.log_odds_ >= self.logodd_thresh_] = 1 MAP['map'][self.log_odds_ < self.logodd_thresh_] = 0 self.MAP_ = MAP
def Twoglobalpos(lidar_hit, joint_angles, body_angles, pose=None, Particles=None): neck_angle = joint_angles[0] # yaw wrt body frame head_angle = joint_angles[1] # pitch wrt body frame roll_gb = body_angles[0] pitch_gb = body_angles[1] yaw_gb = body_angles[ 2] # using imu's yaw has better performance than pose's yaw # lidar wrt head z_hl = 0.15 H_hl = np.array([[1, 0, 0, 0], [0, 1, 0, 0], [0, 0, 1, z_hl], [0, 0, 0, 1]]) # no rotation # head wrt body z_bh = 0.33 T_bh = np.array([[1, 0, 0, 0], [0, 1, 0, 0], [0, 0, 1, z_bh], [0, 0, 0, 1]]) Rz = tf.rot_z_axis(neck_angle) Rz = tf.homo_transform(Rz, np.array([0, 0, 1])) Ry = tf.rot_y_axis(head_angle) Ry = tf.homo_transform(Ry, np.array([0, 0, 1])) R_bh = np.dot(Rz, Ry) H_bh = np.dot(T_bh, R_bh) if Particles is None: # for mapping # body wrt world x_gb = pose[0] y_gb = pose[1] z_gb = 0.93 T_gb = np.array([[1, 0, 0, x_gb], [0, 1, 0, y_gb], [0, 0, 1, z_gb], [0, 0, 0, 1]]) Rb2g_yaw = tf.rot_z_axis(yaw_gb) Rb2g_pitch = tf.rot_y_axis(pitch_gb) Rb2g_roll = tf.rot_x_axis(roll_gb) Hb2g_yaw = tf.homo_transform(Rb2g_yaw, np.array([0, 0, 1])) Hb2g_pitch = tf.homo_transform(Rb2g_pitch, np.array([0, 0, 1])) Hb2g_roll = tf.homo_transform(Rb2g_roll, np.array([0, 0, 1])) R_gb = np.dot(np.dot(Hb2g_yaw, Hb2g_pitch), Hb2g_roll) H_gb = np.dot(T_gb, R_gb) # lidar wrt world H_gl = H_gb.dot(H_bh).dot(H_hl) lidar_hit = np.vstack((lidar_hit, np.ones( (1, lidar_hit.shape[1])))) # 4*n world_hit = np.dot(H_gl, lidar_hit) # ground check, keep hits not on ground not_floor = world_hit[2] > 0.1 world_hit = world_hit[:, not_floor] return world_hit[:3, :] else: # for particles update nums = Particles.shape[1] poses = Particles particles_hit = [] lidar_hit = np.vstack((lidar_hit, np.ones((1, lidar_hit.shape[1])))) for i in range(nums): # body wrt world T_gb = np.array([[1, 0, 0, poses[0, i]], [0, 1, 0, poses[1, i]], [0, 0, 1, 0.93], [0, 0, 0, 1]]) yaw_gb = poses[2, i] Rb2g_yaw = tf.rot_z_axis(yaw_gb) Rb2g_pitch = tf.rot_y_axis(pitch_gb) Rb2g_roll = tf.rot_x_axis(roll_gb) Hb2g_yaw = tf.homo_transform(Rb2g_yaw, np.array([0, 0, 1])) Hb2g_pitch = tf.homo_transform(Rb2g_pitch, np.array([0, 0, 1])) Hb2g_roll = tf.homo_transform(Rb2g_roll, np.array([0, 0, 1])) R_gb = np.dot(np.dot(Hb2g_yaw, Hb2g_pitch), Hb2g_roll) H_gb = np.dot(T_gb, R_gb) # lidar wrt world H_gl = H_gb.dot(H_bh).dot(H_hl) world_hit = np.dot(H_gl, lidar_hit)[:3, :] not_floor = world_hit[2] > 0.1 particles_hit.append(world_hit[:, not_floor]) return np.transpose(np.asarray(particles_hit), (1, 2, 0))
def _update(self, t, t0=0, fig='on'): """Update function where we update the """ if t == t0: self._build_first_map(t0, use_lidar_yaw=True) return #TODO: student's input from here n_thresh = 5 MAP = self.MAP_ #trajectory update ranges = self.lidar_.data_[t]["scan"][0] lidar_t = self.lidar_.data_[t]["t"] lidar_pose = self.lidar_.data_[t]["pose"][0] #lidar_yaw = self.lidar_.data_[self.t0]["rpy"][0][2] joint_ind = np.abs(self.joints_.data_["ts"][0] - lidar_t).argmin() #time sync angles = np.array([np.arange(-135, 135.25, 0.25) * np.pi / 180.]) #limit scan range indv_range = np.logical_and((ranges < 30), (ranges > 0.1)) ranges = ranges[indv_range] angles = angles[0] angles = angles[indv_range] x_lidar = ranges * np.cos(angles) y_lidar = ranges * np.sin(angles) length = len(x_lidar) z_lidar = np.zeros(length) w_lidar = np.ones(length) p_lidar = np.vstack([x_lidar, y_lidar, z_lidar, w_lidar]) neck_angle = self.joints_.data_["head_angles"][0][joint_ind] head_angle = self.joints_.data_["head_angles"][1][joint_ind] #lidar2body body_2_lidar_rot = np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)) # Transition from the body to the lidar frame (lidar is 15cm above the head. See config_slam.pdf for more details) body_2_lidar_trans = np.array([0, 0, 0.15]) body_2_lidar_homo = tf.homo_transform(body_2_lidar_rot, body_2_lidar_trans) p_body = np.dot(body_2_lidar_homo, p_lidar) corr = np.zeros(self.num_p_) for i in range(self.num_p_): pose_i = self.particles_[:, i] world_2_body_rot = tf.rot_z_axis(pose_i[2]) world_2_body_trans = np.array([pose_i[0], pose_i[1], 0.93]) world_2_part_homo = tf.homo_transform(world_2_body_rot, world_2_body_trans) p_world_est = np.dot(world_2_part_homo, p_body) ground_ind = np.argwhere(p_world_est[2] < 0.1) p_world_est = np.delete(p_world_est, ground_ind, 1) p_world_est = p_world_est[0:2, :] Ex = np.ceil( (p_world_est[0, :] - MAP['xmin']) / MAP['res']).astype( np.int16) - 1 Ey = np.ceil( (p_world_est[1, :] - MAP['ymin']) / MAP['res']).astype( np.int16) - 1 obst = np.vstack([Ex, Ey]) corr[i] = prob.mapCorrelation(MAP["map"], obst) #update weights self.weights_ = prob.update_weights(self.weights_, corr) max_ = np.argmax(self.weights_) max_pose = self.particles_[:, max_] self.best_p_[:, t] = max_pose ind_x = np.ceil( (max_pose[0] - MAP['xmin']) / MAP['res']).astype(np.int16) - 1 ind_y = np.ceil( (max_pose[1] - MAP['ymin']) / MAP['res']).astype(np.int16) - 1 self.best_p_indices_[0, t] = ind_x self.best_p_indices_[1, t] = ind_y if t == 1: self.best_p_indices_[0, t - 1] = ind_x self.best_p_indices_[1, t - 1] = ind_y n_eff = 1.0 / (np.sum(self.weights_)**2) if n_eff < self.percent_eff_p_thresh_ * self.num_p_: self.particles_, self.weights_ = prob.stratified_resampling( self.particles_, self.weights_, self.num_p_) #self.time_ = np.empty(self.num_data_) #map_update world_2_body_rot = tf.rot_z_axis(max_pose[2]) world_2_body_trans = np.array([max_pose[0], max_pose[1], 0.93]) world_2_part_homo = tf.homo_transform(world_2_body_rot, world_2_body_trans) p_world_est = np.dot(world_2_part_homo, p_body) ground_ind = np.argwhere(p_world_est[2] < 0.1) p_world_est = np.delete(p_world_est, ground_ind, 1) p_world_est = p_world_est[0:2, :] #Ex = np.ceil((p_world_est[0,:] - MAP['xmin']) / MAP['res'] ).astype(np.int16)-1 #Ey = np.ceil((p_world_est[1,:] - MAP['ymin']) / MAP['res'] ).astype(np.int16)-1 #map into map index sx = np.ceil( (max_pose[0] - MAP['xmin']) / MAP['res']).astype(np.int16) - 1 sy = np.ceil( (max_pose[1] - MAP['xmin']) / MAP['res']).astype(np.int16) - 1 Ex = np.ceil((p_world_est[0, :] - MAP['xmin']) / MAP['res']).astype( np.int16) - 1 Ey = np.ceil((p_world_est[1, :] - MAP['ymin']) / MAP['res']).astype( np.int16) - 1 #brehensam 2D num = len(Ex) for i in range(num): r = bresenham2D(sx, sy, Ex[i], Ey[i]) r = r.astype(np.int16) self.log_odds_[r[0], r[1]] += np.log(self.p_false_) self.log_odds_[Ex, Ey] += (np.log(self.p_true_) - np.log(self.p_false_)) MAP["map"] = MAP["map"].astype(np.float64) MAP["map"] += self.log_odds_ MAP["map"] = 1.0 - 1.0 / (1.0 + np.exp(MAP["map"])) obst = MAP["map"] > self.p_thresh_ free = MAP["map"] < 0.2 unexp = (MAP["map"] > 0.2) & (MAP["map"] < self.p_thresh_) MAP["map"][obst] = 0 MAP["map"][free] = 1 MAP["map"][unexp] = 0.5 #End student's input self.MAP_ = MAP return self.MAP_
def _build_first_map(self, t0=0, use_lidar_yaw=True): """Build the first map using first lidar""" self.t0 = t0 # Extract a ray from lidar data MAP = self.MAP_ print('\n--------Doing build the first map--------') #TODO: student's input from here ##Get data from Lidar data, joint data & time sync ranges = self.lidar_.data_[self.t0]["scan"][0] lidar_t = self.lidar_.data_[self.t0]["t"] lidar_pose = self.lidar_.data_[self.t0]["pose"][0] lidar_yaw = self.lidar_.data_[self.t0]["rpy"][0][2] joint_ind = np.abs(self.joints_.data_["ts"][0] - lidar_t).argmin() #time sync angles = np.array([np.arange(-135, 135.25, 0.25) * np.pi / 180.]) #limit scan range indv_range = np.logical_and((ranges < 30), (ranges > 0.1)) ranges = ranges[indv_range] angles = angles[0] angles = angles[indv_range] #x,y positions in lidar frame x_lidar = ranges * np.cos(angles) y_lidar = ranges * np.sin(angles) length = len(x_lidar) z_lidar = np.zeros(length) w_lidar = np.ones(length) p_lidar = np.vstack([x_lidar, y_lidar, z_lidar, w_lidar]) neck_angle = self.joints_.data_["head_angles"][0][joint_ind] head_angle = self.joints_.data_["head_angles"][1][joint_ind] ## lidar2body & body2world #lidar2body body_2_lidar_rot = np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)) # Transition from the body to the lidar frame (lidar is 15cm above the head. See config_slam.pdf for more details) body_2_lidar_trans = np.array([0, 0, 0.15]) body_2_lidar_homo = tf.homo_transform(body_2_lidar_rot, body_2_lidar_trans) p_body = np.dot(body_2_lidar_homo, p_lidar) #body2world world_2_body_rot = tf.rot_z_axis(lidar_yaw) world_2_body_trans = np.array([lidar_pose[0], lidar_pose[1], 0.93]) world_2_part_homo = tf.homo_transform(world_2_body_rot, world_2_body_trans) p_world = np.dot(world_2_part_homo, p_body) #ground removal ground_ind = np.argwhere(p_world[2] < 0.1) p_world = np.delete(p_world, ground_ind, 1) p_world = p_world[0:2, :] #map into map index sx = np.ceil( (lidar_pose[0] - MAP['xmin']) / MAP['res']).astype(np.int16) - 1 sy = np.ceil( (lidar_pose[1] - MAP['xmin']) / MAP['res']).astype(np.int16) - 1 Ex = np.ceil( (p_world[0, :] - MAP['xmin']) / MAP['res']).astype(np.int16) - 1 Ey = np.ceil( (p_world[1, :] - MAP['ymin']) / MAP['res']).astype(np.int16) - 1 #brehensam 2D num = len(Ex) for i in range(num): r = bresenham2D(sx, sy, Ex[i], Ey[i]) r = r.astype(np.int16) self.log_odds_[r[0], r[1]] += np.log(self.p_false_) self.log_odds_[Ex, Ey] += (np.log(self.p_true_) - np.log(self.p_false_)) MAP["map"] = MAP["map"].astype(np.float64) MAP["map"] += self.log_odds_ MAP["map"] = 1.0 - 1.0 / (1.0 + np.exp(MAP["map"])) obst = MAP["map"] > self.p_thresh_ free = MAP["map"] < 0.2 unexp = (MAP["map"] > 0.2) & (MAP["map"] < self.p_thresh_) MAP["map"][obst] = 0 MAP["map"][free] = 1 MAP["map"][unexp] = 0.5 #End student's input self.MAP_ = MAP
def _update(self, t, t0=0, fig='on'): """Update function where we update the """ # MAP = self.MAP_ if t == t0: self._build_first_map(t0, use_lidar_yaw=True) return #TODO: student's input from here tj0 = self.getJointTime(t) neck_angle, head_angle = self.joints_.data_['head_angles'][:, tj0][ 0], self.joints_.data_['head_angles'][:, tj0][1] body_2_lidar_rot = tf.homo_transform( np.dot(tf.rot_z_axis(neck_angle), tf.rot_y_axis(head_angle)), [0, 0, 0]) scan = self.lidar_.data_[t]['scan'][0] xscan = np.cos(self.lidar_angles) * scan yscan = np.sin(self.lidar_angles) * scan zscan = np.zeros((1, xscan.shape[1])) Onescan = np.ones(zscan.shape) corr = [] for i in range(self.num_p_): pose_i = self.particles_[:, i] ground_2_body = tf.homo_transform(tf.rot_z_axis( pose_i[2]), [pose_i[0], pose_i[1], self.h_lidar_]) #Got the transforms ground_2_lidar = np.dot(ground_2_body, body_2_lidar_rot) homoscan = np.vstack((xscan, yscan, zscan, Onescan)) trans_scan = np.dot(ground_2_lidar, homoscan) # vp = np.vstack((xscan,yscan)) # print("zz",min(trans_scan[1])) trans_scan = trans_scan[:, abs(trans_scan[0]) < 20] trans_scan = trans_scan[:, abs(trans_scan[1]) < 20] x_ind, y_ind = self.getMapCoord(trans_scan[0], trans_scan[1]) occupied_indices = np.vstack((x_ind, y_ind)) corr.append(mapCorrelation(self.MAP_['map'], occupied_indices)) # print(self.num_p_) # corr.append(self.getCorrMap(self.MAP_['map'],x_ind,y_ind)) # space = 0.02 # xs = np.arange(pose_i[0]-space,pose_i[0]+space,space/4) # ys = np.arange(pose_i[1]-space,pose_i[1]+space,space/4) #self.weights_[i] = self.weights_[i]*np.sum(mapCorrelation(self.MAP_['map'], np.array([self.MAP_['xmin'],self.MAP_['xmax']]), \ # np.array([self.MAP_['ymin'],self.MAP_['ymax']]), vp, xs, ys)) #self.weights_[i] = self.weights_[i]*mapCorrelation(self.MAP_['map'],occupied_indices) #self.weights_ = self.weights_/np.sum(self.weights_) corr = np.asarray(corr) self.weights_ = prob.update_weights(self.weights_, corr) best_p_i = np.argmax(self.weights_) best_p = self.particles_[:, best_p_i] x = best_p[0] y = best_p[1] theta = best_p[2] self.buildMAP(t, x, y, theta) self.best_p_[:, t] = best_p self.best_p_indices_[:, t] = self.getMapCoord(x, y) #End student's input # self.MAP_ = MAP return self.MAP_