examples/slam/pose_graph_3d/plot_results.py - ceres-solver - Git at Google

 #!/usr/bin/python
 #
 # Plots the results from the 3D pose graph optimization. It will draw a line
 # between consecutive vertices.  The commandline expects two optional filenames:
 #
 #   ./plot_results.py --initial_poses filename  --optimized_poses filename
 #
 # The files have the following format:
 #   ID x y z q_x q_y q_z q_w

 from mpl_toolkits.mplot3d import Axes3D
 import matplotlib.pyplot as plot
 import numpy
 import sys
 from optparse import OptionParser

 def set_axes_equal(axes):
     ''' Sets the axes of a 3D plot to have equal scale. '''
     x_limits = axes.get_xlim3d()
     y_limits = axes.get_ylim3d()
     z_limits = axes.get_zlim3d()

     x_range = abs(x_limits[1] - x_limits[0])
     x_middle = numpy.mean(x_limits)
     y_range = abs(y_limits[1] - y_limits[0])
     y_middle = numpy.mean(y_limits)
     z_range = abs(z_limits[1] - z_limits[0])
     z_middle = numpy.mean(z_limits)

     length = 0.5 * max([x_range, y_range, z_range])

     axes.set_xlim3d([x_middle - length, x_middle + length])
     axes.set_ylim3d([y_middle - length, y_middle + length])
     axes.set_zlim3d([z_middle - length, z_middle + length])

 parser = OptionParser()
 parser.add_option("--initial_poses", dest="initial_poses",
                   default="", help="The filename that contains the original poses.")
 parser.add_option("--optimized_poses", dest="optimized_poses",
                   default="", help="The filename that contains the optimized poses.")
 parser.add_option("-e", "--axes_equal", action="store_true", dest="axes_equal",
                   default="", help="Make the plot axes equal.")
 (options, args) = parser.parse_args()

 # Read the original and optimized poses files.
 poses_original = None
 if options.initial_poses != '':
   poses_original = numpy.genfromtxt(options.initial_poses,
                                     usecols = (1, 2, 3))

 poses_optimized = None
 if options.optimized_poses != '':
   poses_optimized = numpy.genfromtxt(options.optimized_poses,
                                      usecols = (1, 2, 3))

 # Plots the results for the specified poses.
 figure = plot.figure()

 if poses_original is not None:
   axes = plot.subplot(1, 2, 1, projection='3d')
   plot.plot(poses_original[:, 0], poses_original[:, 1], poses_original[:, 2],
             '-', alpha=0.5, color="green")
   plot.title('Original')
   if options.axes_equal:
     axes.set_aspect('equal')
     set_axes_equal(axes)


 if poses_optimized is not None:
   axes = plot.subplot(1, 2, 2, projection='3d')
   plot.plot(poses_optimized[:, 0], poses_optimized[:, 1], poses_optimized[:, 2],
             '-', alpha=0.5, color="blue")
   plot.title('Optimized')
   if options.axes_equal:
     axes.set_aspect('equal')
     set_axes_equal(plot.gca())


 # Show the plot and wait for the user to close.
 plot.show()
	#!/usr/bin/python
	#
	# Plots the results from the 3D pose graph optimization. It will draw a line
	# between consecutive vertices. The commandline expects two optional filenames:
	#
	# ./plot_results.py --initial_poses filename --optimized_poses filename
	#
	# The files have the following format:
	# ID x y z q_x q_y q_z q_w

	from mpl_toolkits.mplot3d import Axes3D
	import matplotlib.pyplot as plot
	import numpy
	import sys
	from optparse import OptionParser

	def set_axes_equal(axes):
	''' Sets the axes of a 3D plot to have equal scale. '''
	x_limits = axes.get_xlim3d()
	y_limits = axes.get_ylim3d()
	z_limits = axes.get_zlim3d()

	x_range = abs(x_limits[1] - x_limits[0])
	x_middle = numpy.mean(x_limits)
	y_range = abs(y_limits[1] - y_limits[0])
	y_middle = numpy.mean(y_limits)
	z_range = abs(z_limits[1] - z_limits[0])
	z_middle = numpy.mean(z_limits)

	length = 0.5 * max([x_range, y_range, z_range])

	axes.set_xlim3d([x_middle - length, x_middle + length])
	axes.set_ylim3d([y_middle - length, y_middle + length])
	axes.set_zlim3d([z_middle - length, z_middle + length])

	parser = OptionParser()
	parser.add_option("--initial_poses", dest="initial_poses",
	default="", help="The filename that contains the original poses.")
	parser.add_option("--optimized_poses", dest="optimized_poses",
	default="", help="The filename that contains the optimized poses.")
	parser.add_option("-e", "--axes_equal", action="store_true", dest="axes_equal",
	default="", help="Make the plot axes equal.")
	(options, args) = parser.parse_args()

	# Read the original and optimized poses files.
	poses_original = None
	if options.initial_poses != '':
	poses_original = numpy.genfromtxt(options.initial_poses,
	usecols = (1, 2, 3))

	poses_optimized = None
	if options.optimized_poses != '':
	poses_optimized = numpy.genfromtxt(options.optimized_poses,
	usecols = (1, 2, 3))

	# Plots the results for the specified poses.
	figure = plot.figure()

	if poses_original is not None:
	axes = plot.subplot(1, 2, 1, projection='3d')
	plot.plot(poses_original[:, 0], poses_original[:, 1], poses_original[:, 2],
	'-', alpha=0.5, color="green")
	plot.title('Original')
	if options.axes_equal:
	axes.set_aspect('equal')
	set_axes_equal(axes)


	if poses_optimized is not None:
	axes = plot.subplot(1, 2, 2, projection='3d')
	plot.plot(poses_optimized[:, 0], poses_optimized[:, 1], poses_optimized[:, 2],
	'-', alpha=0.5, color="blue")
	plot.title('Optimized')
	if options.axes_equal:
	axes.set_aspect('equal')
	set_axes_equal(plot.gca())


	# Show the plot and wait for the user to close.
	plot.show()