# this is the three dimensional configuration space for rrt # !/usr/bin/env python3 # -*- coding: utf-8 -*- """ @author: yue qi """ import numpy as np # from utils3D import OBB2AABB def R_matrix(z_angle,y_angle,x_angle): # s angle: row; y angle: pitch; z angle: yaw # generate rotation matrix in SO3 # RzRyRx = R, ZYX intrinsic rotation # also (r1,r2,r3) in R3*3 in {W} frame # used in obb.O # [[R p] # [0T 1]] gives transformation from body to world return np.array([[np.cos(z_angle), -np.sin(z_angle), 0.0], [np.sin(z_angle), np.cos(z_angle), 0.0], [0.0, 0.0, 1.0]])@ \ np.array([[np.cos(y_angle), 0.0, np.sin(y_angle)], [0.0, 1.0, 0.0], [-np.sin(y_angle), 0.0, np.cos(y_angle)]])@ \ np.array([[1.0, 0.0, 0.0], [0.0, np.cos(x_angle), -np.sin(x_angle)], [0.0, np.sin(x_angle), np.cos(x_angle)]]) def getblocks(): # AABBs block = [[4.00e+00, 1.20e+01, 0.00e+00, 5.00e+00, 2.00e+01, 5.00e+00], [5.5e+00, 1.20e+01, 0.00e+00, 1.00e+01, 1.30e+01, 5.00e+00], [1.00e+01, 1.20e+01, 0.00e+00, 1.40e+01, 1.30e+01, 5.00e+00], [1.00e+01, 9.00e+00, 0.00e+00, 2.00e+01, 1.00e+01, 5.00e+00], [9.00e+00, 6.00e+00, 0.00e+00, 1.00e+01, 1.00e+01, 5.00e+00]] Obstacles = [] for i in block: i = np.array(i) Obstacles.append([j for j in i]) return np.array(Obstacles) def getballs(): spheres = [[2.0,6.0,2.5,1.0],[14.0,14.0,2.5,2]] Obstacles = [] for i in spheres: Obstacles.append([j for j in i]) return np.array(Obstacles) def getAABB(blocks): # used for Pyrr package for detecting collision AABB = [] for i in blocks: AABB.append(np.array([np.add(i[0:3], -0), np.add(i[3:6], 0)])) # make AABBs alittle bit of larger return AABB def getAABB2(blocks): # used in lineAABB AABB = [] for i in blocks: AABB.append(aabb(i)) return AABB def add_block(block = [1.51e+01, 0.00e+00, 2.10e+00, 1.59e+01, 5.00e+00, 6.00e+00]): return block class aabb(object): # make AABB out of blocks, # P: center point # E: extents # O: Rotation matrix in SO(3), in {w} def __init__(self,AABB): self.P = [(AABB[3] + AABB[0])/2, (AABB[4] + AABB[1])/2, (AABB[5] + AABB[2])/2]# center point self.E = [(AABB[3] - AABB[0])/2, (AABB[4] - AABB[1])/2, (AABB[5] - AABB[2])/2]# extents self.O = [[1,0,0],[0,1,0],[0,0,1]] class obb(object): # P: center point # E: extents # O: Rotation matrix in SO(3), in {w} def __init__(self, P, E, O): self.P = P self.E = E self.O = O self.T = np.vstack([np.column_stack([self.O.T,-self.O.T@self.P]),[0,0,0,1]]) class env(): def __init__(self, xmin=0, ymin=0, zmin=0, xmax=20, ymax=20, zmax=5, resolution=1): # def __init__(self, xmin=-5, ymin=0, zmin=-5, xmax=10, ymax=5, zmax=10, resolution=1): self.resolution = resolution self.boundary = np.array([xmin, ymin, zmin, xmax, ymax, zmax]) self.blocks = getblocks() self.AABB = getAABB2(self.blocks) self.AABB_pyrr = getAABB(self.blocks) self.balls = getballs() self.OBB = np.array([obb([5.0,7.0,2.5],[0.5,2.0,2.5],R_matrix(135,0,0)), obb([12.0,4.0,2.5],[0.5,2.0,2.5],R_matrix(45,0,0))]) self.start = np.array([2.0, 2.0, 2.0]) self.goal = np.array([6.0, 16.0, 0.0]) self.t = 0 # time def New_block(self): newblock = add_block() self.blocks = np.vstack([self.blocks,newblock]) self.AABB = getAABB2(self.blocks) self.AABB_pyrr = getAABB(self.blocks) def move_start(self, x): self.start = x def move_block(self, a = [0,0,0], s = 0, v = [0.1,0,0], block_to_move = 0, mode = 'translation'): # t is time , v is velocity in R3, a is acceleration in R3, s is increment ini time, # R is an orthorgonal transform in R3*3, is the rotation matrix # (s',t') = (s + tv, t) is uniform transformation # (s',t') = (s + a, t + s) is a translation if mode == 'translation': ori = np.array(self.blocks[block_to_move]) self.blocks[block_to_move] = \ np.array([ori[0] + a[0],\ ori[1] + a[1],\ ori[2] + a[2],\ ori[3] + a[0],\ ori[4] + a[1],\ ori[5] + a[2]]) self.AABB[block_to_move].P = \ [self.AABB[block_to_move].P[0] + a[0], \ self.AABB[block_to_move].P[1] + a[1], \ self.AABB[block_to_move].P[2] + a[2]] self.t += s # return a range of block that the block might moved a = self.blocks[block_to_move] return np.array([a[0] - self.resolution, a[1] - self.resolution, a[2] - self.resolution, \ a[3] + self.resolution, a[4] + self.resolution, a[5] + self.resolution]), \ np.array([ori[0] - self.resolution, ori[1] - self.resolution, ori[2] - self.resolution, \ ori[3] + self.resolution, ori[4] + self.resolution, ori[5] + self.resolution]) # return a,ori # (s',t') = (Rx, t) def move_OBB(self, obb_to_move = 0, theta=[0,0,0], translation=[0,0,0]): # theta stands for rotational angles around three principle axis in world frame # translation stands for translation in the world frame ori = [self.OBB[obb_to_move]] # move obb position self.OBB[obb_to_move].P = \ [self.OBB[obb_to_move].P[0] + translation[0], self.OBB[obb_to_move].P[1] + translation[1], self.OBB[obb_to_move].P[2] + translation[2]] # Calculate orientation self.OBB[obb_to_move].O = R_matrix(z_angle=theta[0],y_angle=theta[1],x_angle=theta[2]) # generating transformation matrix self.OBB[obb_to_move].T = np.vstack([np.column_stack([self.OBB[obb_to_move].O.T,\ -self.OBB[obb_to_move].O.T@self.OBB[obb_to_move].P]),[translation[0],translation[1],translation[2],1]]) return self.OBB[obb_to_move], ori[0] if __name__ == '__main__': newenv = env()