""" Grid based Dijkstra planning author: Atsushi Sakai(@Atsushi_twi) """ import matplotlib.pyplot as plt import math show_animation = True class Dijkstra: def __init__(self, ox, oy, reso, rr): """ Initialize map for a star planning ox: x position list of Obstacles [m] oy: y position list of Obstacles [m] reso: grid resolution [m] rr: robot radius[m] """ self.reso = reso self.rr = rr self.calc_obstacle_map(ox, oy) self.motion = self.get_motion_model() class Node: def __init__(self, x, y, cost, pind): self.x = x # index of grid self.y = y # index of grid self.cost = cost self.pind = pind def __str__(self): return str(self.x) + "," + str(self.y) + "," + str(self.cost) + "," + str(self.pind) def planning(self, sx, sy, gx, gy): """ dijkstra path search input: sx: start x position [m] sy: start y position [m] gx: goal x position [m] gx: goal x position [m] output: rx: x position list of the final path ry: y position list of the final path """ nstart = self.Node(self.calc_xyindex(sx, self.minx), self.calc_xyindex(sy, self.miny), 0.0, -1) ngoal = self.Node(self.calc_xyindex(gx, self.minx), self.calc_xyindex(gy, self.miny), 0.0, -1) openset, closedset = dict(), dict() openset[self.calc_index(nstart)] = nstart while 1: c_id = min(openset, key=lambda o: openset[o].cost) current = openset[c_id] # show graph if show_animation: # pragma: no cover plt.plot(self.calc_position(current.x, self.minx), self.calc_position(current.y, self.miny), "xc") if len(closedset.keys()) % 10 == 0: plt.pause(0.001) if current.x == ngoal.x and current.y == ngoal.y: print("Find goal") ngoal.pind = current.pind ngoal.cost = current.cost break # Remove the item from the open set del openset[c_id] # Add it to the closed set closedset[c_id] = current # expand search grid based on motion model for i, _ in enumerate(self.motion): node = self.Node(current.x + self.motion[i][0], current.y + self.motion[i][1], current.cost + self.motion[i][2], c_id) n_id = self.calc_index(node) if n_id in closedset: continue if not self.verify_node(node): continue if n_id not in openset: openset[n_id] = node # Discover a new node else: if openset[n_id].cost >= node.cost: # This path is the best until now. record it! openset[n_id] = node rx, ry = self.calc_final_path(ngoal, closedset) return rx, ry def calc_final_path(self, ngoal, closedset): # generate final course rx, ry = [self.calc_position(ngoal.x, self.minx)], [ self.calc_position(ngoal.y, self.miny)] pind = ngoal.pind while pind != -1: n = closedset[pind] rx.append(self.calc_position(n.x, self.minx)) ry.append(self.calc_position(n.y, self.miny)) pind = n.pind return rx, ry def calc_heuristic(self, n1, n2): w = 1.0 # weight of heuristic d = w * math.sqrt((n1.x - n2.x)**2 + (n1.y - n2.y)**2) return d def calc_position(self, index, minp): pos = index*self.reso+minp return pos def calc_xyindex(self, position, minp): return round((position - minp)/self.reso) def calc_index(self, node): return (node.y - self.miny) * self.xwidth + (node.x - self.minx) def verify_node(self, node): px = self.calc_position(node.x, self.minx) py = self.calc_position(node.y, self.miny) if px < self.minx: return False elif py < self.miny: return False elif px >= self.maxx: return False elif py >= self.maxy: return False if self.obmap[node.x][node.y]: return False return True def calc_obstacle_map(self, ox, oy): self.minx = round(min(ox)) self.miny = round(min(oy)) self.maxx = round(max(ox)) self.maxy = round(max(oy)) print("minx:", self.minx) print("miny:", self.miny) print("maxx:", self.maxx) print("maxy:", self.maxy) self.xwidth = round((self.maxx - self.minx)/self.reso) self.ywidth = round((self.maxy - self.miny)/self.reso) print("xwidth:", self.xwidth) print("ywidth:", self.ywidth) # obstacle map generation self.obmap = [[False for i in range(self.ywidth)] for i in range(self.xwidth)] for ix in range(self.xwidth): x = self.calc_position(ix, self.minx) for iy in range(self.ywidth): y = self.calc_position(iy, self.miny) for iox, ioy in zip(ox, oy): d = math.sqrt((iox - x)**2 + (ioy - y)**2) if d <= self.rr: self.obmap[ix][iy] = True break def get_motion_model(self): # dx, dy, cost motion = [[1, 0, 1], [0, 1, 1], [-1, 0, 1], [0, -1, 1], [-1, -1, math.sqrt(2)], [-1, 1, math.sqrt(2)], [1, -1, math.sqrt(2)], [1, 1, math.sqrt(2)]] return motion def main(): print(__file__ + " start!!") # start and goal position sx = -5.0 # [m] sy = -5.0 # [m] gx = 50.0 # [m] gy = 50.0 # [m] grid_size = 2.0 # [m] robot_radius = 1.0 # [m] # set obstacle positions ox, oy = [], [] for i in range(-10, 60): ox.append(i) oy.append(-10.0) for i in range(-10, 60): ox.append(60.0) oy.append(i) for i in range(-10, 61): ox.append(i) oy.append(60.0) for i in range(-10, 61): ox.append(-10.0) oy.append(i) for i in range(-10, 40): ox.append(20.0) oy.append(i) for i in range(0, 40): ox.append(40.0) oy.append(60.0 - i) if show_animation: # pragma: no cover plt.plot(ox, oy, ".k") plt.plot(sx, sy, "og") plt.plot(gx, gy, "xb") plt.grid(True) plt.axis("equal") dijkstra = Dijkstra(ox, oy, grid_size, robot_radius) rx, ry = dijkstra.planning(sx, sy, gx, gy) if show_animation: # pragma: no cover plt.plot(rx, ry, "-r") plt.show() if __name__ == '__main__': main()