一文教你用python编写Dijkstra算法进行机器人路径规划
目录
- 前言
- 一、算法原理
- 二、程序代码
- 三、运行结果
- 四、 A*算法:Djikstra算法的改进
- 总结
前言
为了机器人在寻路的过程中避障并且找到最短距离,我们需要使用一些算法进行路径规划(Path Planning),常用的算法有Djikstra算法、A*算法等等,在github上有一个非常好的项目叫做pythonRobotics,其中给出了源代码,参考代码,可以对Djikstra算法有更深的了解。
一、算法原理
如图所示,Dijkstra算法要解决的是一个有向权重图中最短路径的寻找问题,图中红色节点1代表起始节点,蓝色节点6代表目标结点。箭头上的数字代表两个结点中的的距离,也就是模型中所谓的代价(cost)。
贪心算法需要设立两个集合,open_set(开集)和closed_set(闭集),然后根据以下程序进行操作:
- 把初始结点放入到open_set中;
- 把open_set中代价最小的节点取出来放入到closed_set中,并且作为当前节点;
- 把与当前节点相邻的节点放入到open_set中,如果代价更小更新代价
- 重复2-3过程,直到找到终点。
注意open_set中的代价是可变的,而closed_set中的代价已经是最小的代价了,这也是为什么叫做open和close的原因。
至于为什么closed_set中的代价是最小的,是因为我们使用了贪心算法,既然已经把节点加入到了close中,那么初始点到close节点中的距离就比到open中的距离小了,无论如何也不可能找到比它更小的了。
二、程序代码
""" 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, resolution, robot_radius): """ Initialize map for a star planning ox: x position list of Obstacles [m] oy: y position list of Obstacles [m] resolution: grid resolution [m] rr: robot radius[m] """ self.min_x = None self.min_y = None self.max_x = None self.max_y = None self.x_width = None self.y_width = None self.obstacle_map = None self.resolution = resolution self.robot_radius = robot_radius self.calc_obstacle_map(ox, oy) self.motion = self.get_motion_model() class Node: def __init__(self, x, y, cost, parent_index): self.x = x # index of grid self.y = y # index of grid self.cost = cost self.parent_index = parent_index # index of previous Node def __str__(self): return str(self.x) + "," + str(self.y) + "," + str( self.cost) + "," + str(self.parent_index) def planning(self, sx, sy, gx, gy): """ dijkstra path search input: s_x: start x position [m] s_y: 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 """ start_node = self.Node(self.calc_xy_index(sx, self.min_x), self.calc_xy_index(sy, self.min_y), 0.0, -1) goal_node = self.Node(self.calc_xy_index(gx, self.min_x), self.calc_xy_index(gy, self.min_y), 0.0, -1) open_set, closed_set = dict(), dict() open_set[self.calc_index(start_node)] = start_node while 1: c_id = min(open_set, key=lambda o: open_set[o].cost) current = open_set[c_id] # show graph if show_animation: # pragma: no cover plt.plot(self.calc_position(current.x, self.min_x), self.calc_position(current.y, self.min_y), "xc") # for stopping simulation with the esc key. plt.gcf().canvas.mpl_connect( 'key_release_event', www.cppcns.com lambda event: [exit(0) if event.key == 'escape' else None]) if len(closed_set.keys()) % 10 == 0: plt.pause(0.001) if current.x == goal_node.x and current.y == goal_node.y: print("Find goal") goal_node.parent_index = current.parent_index goal_node.cost = current.cost break # Remove the item from the open set del open_set[c_id] # Add it to the closed set closed_set[c_id] = current # expand search grid based on motion model for move_x, move_y, move_cost in self.motion: node = self.Node(current.x + move_x, current.y + move_y, current.cost + move_cost, c_id) n_id = self.calc_index(node) if n_id in closed_set: continue if not self.verify_node(node): continue if n_id not in open_set: open_set[n_id] = node # Discover a new node else: if open_set[n_id].cost >= node.cost: # This path is the best until now. record it! open_set[n_id] = node rx, ry = self.calc_final_path(goal_node, c编程客栈losed_set) return rx, ry def calc_final_path(self, goal_node, closed_set): # generate final course rx, ry = [self.calc_position(goal_node.x, self.min_x)], [ self.calc_position(goal_node.y, self.min_y)] parent_index = goal_node.parent_index while parent_index != -1: n = closed_set[parent_index] rx.append(self.calc_position(n.x, self.min_x)) ry.append(self.calc_position(n.y, self.min_y)) parent_index = n.parent_index return rx, ry def calc_position(self, index, minp): pos = index * self.resolution + minp return pos def calc_xy_index(self, position, minp): return round((position - minp) / self.resolution) def calc_index(self, node): return (node.y - self.min_y) * self.x_width + (node.x - self.min_x) def verify_node(self, node): px = self.calc_position(node.x, self.min_x) py = self.calc_position(node.y, self.min_y) if px < self.min_x: http://www.cppcns.com return False if py < self.min_y: return False if px >= self.max_x: return False if py >= self.max_y: return False if self.obstacle_map[node.x][node.y]: return False return True def calc_obstacle_map(self, ox, oy): self.min_x = round(min(ox)) self.min_y = round(min(oy)) self.max_x = round(max(ox)) self.max_y = round(max(oy)) print("min_x:", self.min_x) print("min_y:", self.min_y) print("max_x:", self.max_x) print("max_y:", self.max_y) self.x_width = round((self.max_x - self.min_x) / self.resolution) self.y_width = round((self.max_y - self.min_y) / self.resolution) print("x_width:", self.x_width) print("y_width:", self.y_width) # obstacle map generation self.obstacle_map = [[False for _ in range(self.y_width)] for _ in range(self.x_width)] for ix in range(self.x_width): x = self.calc_position(ix, self.min_x) for iy in range(self.y_width): y = self.calc_position(iy, self.min_y) for iox, ioy in zip(ox, oy): d = math.hypot(iox - x, ioy - y) if d <= self.robot_radius: self.obstacle_map[ix][iy] = True break @staticmethod def get_motion_model(): # 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):编程客栈 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: # pragmhttp://www.cppcns.coma: no cover plt.plot(rx, ry, "-r") plt.pause(0.01) plt.show() if __name__ == '__main__': main()
三、运行结果
四、 A*算法:Djikstra算法的改进
Dijkstra算法实际上是贪心搜索算法,算法复杂度为O( n 2 n^2 n2),为了减少无效搜索的次数,我们可以增加一个启发式函数(heuristic),比如搜索点到终点目标的距离,在选择open_set元素的时候,我们将cost变成cost+heuristic,就可以给出搜索的方向性,这样就可以减少南辕北辙的情况。我们可以run一下PythonRobotics中的Astar代码,得到以下结果:
总结
到此这篇关于python编写Dijkstra算法进行机器人路径规划的文章就介绍到这了,更多相关python写Dijkstra算法内容请搜索我们以前的文章或继续浏览下面的相关文章希望大家以后多多支持我们!
精彩评论