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random_obstacle_map.py
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random_obstacle_map.py
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import numpy as np
from rtree import index
from matplotlib.pyplot import Rectangle
import matplotlib.pyplot as plt
import mpl_toolkits.mplot3d.axes3d as Axes3D
class Map:
def __init__(self, obstacle_list, bounds, path_resolution = 0.5, dim = 3):
'''initialise map with given properties'''
self.dim = dim
self.idx = self.get_tree(obstacle_list, dim)
self.len = len(obstacle_list)
self.path_res = path_resolution
self.obstacles = obstacle_list
self.bounds = bounds
@staticmethod
def get_tree(obstacle_list, dim):
'''initialise map with given obstacle_list'''
p = index.Property()
p.dimension = dim
ls = [(i,(*obj,),None) for i, obj in enumerate(obstacle_list)]
return index.Index(ls, properties=p)
def add(self, obstacle):
'''add new obstacle to the list'''
self.idx.insert(self.len, obstacle)
self.obstacles.append(obstacle)
self.len += 1
def collision(self,start,end):
'''find if the ray between start and end collides with obstacles'''
dist = np.linalg.norm(start-end)
n = int(dist/self.path_res)
points = np.linspace(start,end,n)
for p in points:
if self.idx.count((*p,)) != 0 :
return True
return False
def inbounds(self,p):
'''Check if p lies inside map bounds'''
lower,upper = self.bounds
return (lower <= p).all() and (p <= upper).all()
def plotobs(self,ax,scale = 1):
'''plot all obstacles'''
obstacles = scale*np.array(self.obstacles)
if self.dim == 2:
for box in obstacles:
l = box[2] - box[0]
w = box[3] - box[1]
box_plt = Rectangle((box[0], box[1]),l,w,color='k',zorder = 1)
ax.add_patch(box_plt)
elif self.dim == 3:
for box in obstacles:
X, Y, Z = cuboid_data(box)
ax.plot_surface(X, Y, Z, rstride=1, cstride=1, color=(0.1, 0.15, 0.3, 0.2), zorder = 1)
else: print('can not plot for given dimensions')
#to plot obstacle surfaces
def cuboid_data(box):
l = box[3] - box[0]
w = box[4] - box[1]
h = box[5] - box[2]
x = [[0, l, l, 0, 0],
[0, l, l, 0, 0],
[0, l, l, 0, 0],
[0, l, l, 0, 0]]
y = [[0, 0, w, w, 0],
[0, 0, w, w, 0],
[0, 0, 0, 0, 0],
[w, w, w, w, w]]
z = [[0, 0, 0, 0, 0],
[h, h, h, h, h],
[0, 0, h, h, 0],
[0, 0, h, h, 0]]
return box[0] + np.array(x), box[1] + np.array(y), box[2] + np.array(z)
# Generate random obstacle parameters
def random_grid_3D(bounds, density, height):
if max(bounds) >= 50:
x_size = bounds[1]
y_size = bounds[1]
z_size = bounds[1]
else:
x_size = 100
y_size = 100
z_size = 100
# Generate random grid with discrete 0/1 altitude using normal distribtion
mean_E = 0
sigma = 1
k_sigma = density
E = np.random.normal(mean_E, sigma, size=(x_size, y_size))
h = height
# Set the decision threshold
sigma_obstacle = k_sigma * sigma
E = E > sigma_obstacle
E = E.astype(float)
# Generate random altitude to blocks
h_min = 10 # minimal obstacles altitude
E_temp = E
for i in range(x_size):
for j in range(y_size):
#k = range(i - 1 - round(np.random.beta(0.5, 0.5)), i + 1 + round(np.random.beta(0.5, 0.5)), 1)
#l = range(j - 1 - round(np.random.beta(0.5, 0.5)), j + 1 + round(np.random.beta(0.5, 0.5)), 1)
if E_temp[j,i]==1:
hh = round(np.random.normal(0.7*h, 0.5*h))
if hh < h_min:
hh = h_min
elif hh > z_size:
hh = z_size
E[j,i] = hh
return E
# seed = 42, 10, 20, 25
def generate_map(bounds, density, height, start, goal, path_resolution, seed_num=42):
np.random.seed(seed_num)
# Create the obstacles on the map
obstacles_ = random_grid_3D(bounds,density,height)
obstacles = []
if max(bounds) >= 50:
x_size = bounds[1]
y_size = bounds[1]
else:
x_size = 100
y_size = 100
scale_ = bounds[1]/100
for i in range(x_size):
for j in range(y_size):
if obstacles_[i,j] > 0:
ss = round(np.random.normal(3, 1)) # Define the parameter to randomize the obstacle size
obstacles.append([i * scale_, j * scale_, 0, (i+ss)* scale_, (j+ss)* scale_, obstacles_[i,j] * scale_])
# create map with selected obstacles
obstacles = start_goal_mapcheck(start,goal,obstacles)
mapobs = Map(obstacles, bounds, dim = 3, path_resolution=path_resolution)
print('Generate %d obstacles on the random map.'%len(obstacles))
return mapobs, obstacles
# Check if the start point and the goal point on the map
def start_goal_mapcheck(start,goal,obstacles):
obs_pop = []
for i in range(len(obstacles)):
if (start[0] >= obstacles[i][0] and start[0] <= obstacles[i][3] and start[1] >= obstacles[i][1] \
and start[1] <= obstacles[i][4] and start[2] >= obstacles[i][2] and start[2] <= obstacles[i][5]) \
or (goal[0] >= obstacles[i][0] and goal[0] <= obstacles[i][3] and goal[1] >= obstacles[i][1] \
and goal[1] <= obstacles[i][4] and goal[2] >= obstacles[i][2] and goal[2] <= obstacles[i][5]):
obs_pop.append(i)
print("The start point and goal point collides with obstacles!")
for i in range(len(obs_pop)):
obstacles.pop(obs_pop[i])
return obstacles
def main():
# limits on map dimensions
bounds = np.array([0,2])
# Define the density value of the map
density = 2.5
# Define the height parameter of the obstacles on the map
height = 50
# Define the start point and goal point
start = np.array([0,0,5])
goal = np.array([65,65,5])
# create map with selected obstacles
mapobs,obstacles = generate_map(bounds, density, height, start, goal)
# Visualize the obstacle map
fig = plt.figure()
ax = Axes3D.Axes3D(fig)
ax.set_xlim((bounds[0],bounds[1]))
ax.set_ylim((bounds[0],bounds[1]))
ax.set_zlim((bounds[0],bounds[1]))
mapobs.plotobs(ax, scale = 1)
plt.show()
'''Call the main function'''
if __name__ == "__main__":
main()