def __init__(self):
'''
Takes no args. Maybe we could specify colors, lidar params, etc.
'''
# Create the frame
tk.Frame.__init__(self, borderwidth=4, relief='sunken')
self.master.geometry(
str(DISPLAY_CANVAS_SIZE_PIXELS) + "x" +
str(DISPLAY_CANVAS_SIZE_PIXELS))
self.master.title('XV Lidar [ESC to quit]')
self.grid()
self.master.rowconfigure(0, weight=1)
self.master.columnconfigure(0, weight=1)
self.grid(sticky=tk.W + tk.E + tk.N + tk.S)
self.background = DISPLAY_CANVAS_COLOR
# Add a canvas for drawing
self.canvas = tk.Canvas(self, \
width = DISPLAY_CANVAS_SIZE_PIXELS, \
height = DISPLAY_CANVAS_SIZE_PIXELS,\
background = DISPLAY_CANVAS_COLOR)
self.canvas.grid(row = 0, column = 0,\
rowspan = 1, columnspan = 1,\
sticky = tk.W+tk.E+tk.N+tk.S)
# Set up a key event for exit on ESC
self.bind('<Key>', self._key)
# This call gives the frame focus so that it receives input
self.focus_set()
# No scanlines initially
self.lines = []
# Connect to the XVLidar
self.lidar = XVLidar(COM_PORT)
# No scan data to start
self.scandata = []
# Pre-compute some values useful for plotting
scan_angle_rad = [radians(-XVLIDAR_DETECTION_DEG/2 + (float(k)/XVLIDAR_SCAN_SIZE) * \
XVLIDAR_DETECTION_DEG) for k in range(XVLIDAR_SCAN_SIZE)]
self.half_canvas_pix = DISPLAY_CANVAS_SIZE_PIXELS / 2
scale = self.half_canvas_pix / float(XVLIDAR_MAX_SCAN_DIST_MM)
self.cos = [-cos(angle) * scale for angle in scan_angle_rad]
self.sin = [sin(angle) * scale for angle in scan_angle_rad]
# Add scan lines to canvas, to be modified later
self.lines = [self.canvas.create_line(\
self.half_canvas_pix, \
self.half_canvas_pix, \
self.half_canvas_pix + self.sin[k] * XVLIDAR_MAX_SCAN_DIST_MM,\
self.half_canvas_pix + self.cos[k] * XVLIDAR_MAX_SCAN_DIST_MM)
for k in range(XVLIDAR_SCAN_SIZE)]
[
self.canvas.itemconfig(line, fill=DISPLAY_SCAN_LINE_COLOR)
for line in self.lines
]
# Start a new thread and set a flag to let it know when we stop running
thread.start_new_thread(self.grab_scan, ())
self.running = True
MAP_SIZE_PIXELS = 500
MAP_SIZE_METERS = 10
LIDAR_DEVICE = '/dev/ttyACM0'
from breezyslam.algorithms import RMHC_SLAM
from breezyslam.sensors import XVLidar as LaserModel
from xvlidar import XVLidar as Lidar
from roboviz import MapVisualizer
if __name__ == '__main__':
# Connect to Lidar unit
lidar = Lidar(LIDAR_DEVICE)
# Create an RMHC SLAM object with a laser model and optional robot model
slam = RMHC_SLAM(LaserModel(), MAP_SIZE_PIXELS, MAP_SIZE_METERS)
# Set up a SLAM display
display = MapVisualizer(MAP_SIZE_PIXELS, MAP_SIZE_METERS, 'SLAM')
# Initialize an empty trajectory
trajectory = []
# Initialize empty map
mapbytes = bytearray(MAP_SIZE_PIXELS * MAP_SIZE_PIXELS)
while True:
class XVLidarPlotter(tk.Frame):
'''
XVLidarPlotter extends tk.Frame to plot Lidar scans.
'''
def __init__(self):
'''
Takes no args. Maybe we could specify colors, lidar params, etc.
'''
# Create the frame
tk.Frame.__init__(self, borderwidth=4, relief='sunken')
self.master.geometry(
str(DISPLAY_CANVAS_SIZE_PIXELS) + "x" +
str(DISPLAY_CANVAS_SIZE_PIXELS))
self.master.title('XV Lidar [ESC to quit]')
self.grid()
self.master.rowconfigure(0, weight=1)
self.master.columnconfigure(0, weight=1)
self.grid(sticky=tk.W + tk.E + tk.N + tk.S)
self.background = DISPLAY_CANVAS_COLOR
# Add a canvas for drawing
self.canvas = tk.Canvas(self, \
width = DISPLAY_CANVAS_SIZE_PIXELS, \
height = DISPLAY_CANVAS_SIZE_PIXELS,\
background = DISPLAY_CANVAS_COLOR)
self.canvas.grid(row = 0, column = 0,\
rowspan = 1, columnspan = 1,\
sticky = tk.W+tk.E+tk.N+tk.S)
# Set up a key event for exit on ESC
self.bind('<Key>', self._key)
# This call gives the frame focus so that it receives input
self.focus_set()
# No scanlines initially
self.lines = []
# Connect to the XVLidar
self.lidar = XVLidar(COM_PORT)
# No scan data to start
self.scandata = []
# Pre-compute some values useful for plotting
scan_angle_rad = [radians(-XVLIDAR_DETECTION_DEG/2 + (float(k)/XVLIDAR_SCAN_SIZE) * \
XVLIDAR_DETECTION_DEG) for k in range(XVLIDAR_SCAN_SIZE)]
self.half_canvas_pix = DISPLAY_CANVAS_SIZE_PIXELS / 2
scale = self.half_canvas_pix / float(XVLIDAR_MAX_SCAN_DIST_MM)
self.cos = [-cos(angle) * scale for angle in scan_angle_rad]
self.sin = [sin(angle) * scale for angle in scan_angle_rad]
# Add scan lines to canvas, to be modified later
self.lines = [self.canvas.create_line(\
self.half_canvas_pix, \
self.half_canvas_pix, \
self.half_canvas_pix + self.sin[k] * XVLIDAR_MAX_SCAN_DIST_MM,\
self.half_canvas_pix + self.cos[k] * XVLIDAR_MAX_SCAN_DIST_MM)
for k in range(XVLIDAR_SCAN_SIZE)]
[
self.canvas.itemconfig(line, fill=DISPLAY_SCAN_LINE_COLOR)
for line in self.lines
]
# Start a new thread and set a flag to let it know when we stop running
thread.start_new_thread(self.grab_scan, ())
self.running = True
# Runs on its own thread
def grab_scan(self):
while True:
# Lidar sends 360 (distance, quality) pairs, which may be empty on start
self.scandata = [pair[0] for pair in self.lidar.getScan()]
self.count += 1
if not self.running:
break
# yield to plotting thread
sleep(.0001)
def run(self):
'''
Call this when you're ready to run.
'''
# Record start time and initiate a count of scans for testing
self.count = 0
self.start_sec = time()
self.showcount = 0
# Start the recursive timer-task
plotter._task()
# Start the GUI
plotter.mainloop()
def destroy(self):
'''
Called automagically when user clicks X to close window.
'''
self._quit()
def _quit(self):
self.running = False
elapsed_sec = time() - self.start_sec
del self.lidar
exit(0)
def _key(self, event):
# Make sure the frame is receiving input!
self.focus_force()
if event.keysym == 'Escape':
self._quit()
def _task(self):
# Modify the displayed lines according to the current scan
[self.canvas.coords(self.lines[k],
self.half_canvas_pix, \
self.half_canvas_pix, \
self.half_canvas_pix + self.sin[k] * self.scandata[k],\
self.half_canvas_pix + self.cos[k] * self.scandata[k]) \
for k in range(len(self.scandata))]
# Reschedule this task immediately
self.after(1, self._task)
# Record another display for reporting performance
self.showcount += 1
MAP_SIZE_PIXELS = 500
MAP_SIZE_METERS = 3
LIDAR_DEVICE = '/dev/ttyACM0'
from breezyslam.algorithms import VLP_SLAM
from breezyslam.components import XVLidar as LaserModel
from xvlidar import XVLidar as Lidar
from cvslamshow import SlamShow
if __name__ == '__main__':
# Connect to Lidar unit
lidar = Lidar(LIDAR_DEVICE)
# Create an RMHC SLAM object with a laser model and optional robot model
slam = VLP_SLAM(LaserModel(), MAP_SIZE_PIXELS, MAP_SIZE_METERS)
# Set up a SLAM display
display = SlamShow(MAP_SIZE_PIXELS, MAP_SIZE_METERS*1000/MAP_SIZE_PIXELS, 'SLAM')
# Initialize an empty trajectory
trajectory = []
# Initialize empty map
mapbytes = bytearray(MAP_SIZE_PIXELS * MAP_SIZE_PIXELS)
#wait for positioning to be ready
ready = "0"
def signal_handler(signa, frame):
robot.stop()
sys.exit(0)
signal.signal(signal.SIGINT, signal_handler)
try:
print('Initializing..')
robot = NexusRobot(ROBOT_DEVICE)
print('Initialized')
t = Thread(target=telem, args=(robot, ))
t.daemon = True
t.start()
odomRobot = NexusRobotOd()
# Connect to Lidar unit
lidar = Lidar(LIDAR_DEVICE)
# Create an RMHC SLAM object with a laser model and optional robot model
slam = RMHC_SLAM(LaserModel(), MAP_SIZE_PIXELS, MAP_SIZE_METERS)
# Set up a SLAM display
display = SlamShow(MAP_SIZE_PIXELS,
MAP_SIZE_METERS * 1000 / MAP_SIZE_PIXELS, 'SLAM')
# Initialize an empty trajectory
trajectory = []
# Initialize empty map
mapbytes = bytearray(MAP_SIZE_PIXELS * MAP_SIZE_PIXELS)
while True:
def __init__(self):
'''
Takes no args. Maybe we could specify colors, lidar params, etc.
'''
# Create the frame
tk.Frame.__init__(self, borderwidth = 4, relief = 'sunken')
self.master.geometry(str(DISPLAY_CANVAS_SIZE_PIXELS)+ "x" + str(DISPLAY_CANVAS_SIZE_PIXELS))
self.master.title('XV Lidar [ESC to quit]')
self.grid()
self.master.rowconfigure(0, weight = 1)
self.master.columnconfigure(0, weight = 1)
self.grid(sticky = tk.W+tk.E+tk.N+tk.S)
self.background = DISPLAY_CANVAS_COLOR
# Add a canvas for drawing
self.canvas = tk.Canvas(self, \
width = DISPLAY_CANVAS_SIZE_PIXELS, \
height = DISPLAY_CANVAS_SIZE_PIXELS,\
background = DISPLAY_CANVAS_COLOR)
self.canvas.grid(row = 0, column = 0,\
rowspan = 1, columnspan = 1,\
sticky = tk.W+tk.E+tk.N+tk.S)
# Set up a key event for exit on ESC
self.bind('<Key>', self._key)
# This call gives the frame focus so that it receives input
self.focus_set()
# No scanlines initially
self.lines = []
# Connect to the XVLidar
self.lidar = XVLidar(COM_PORT)
# No scan data to start
self.scandata = []
# Pre-compute some values useful for plotting
scan_angle_rad = [radians(-XVLIDAR_DETECTION_DEG/2 + (float(k)/XVLIDAR_SCAN_SIZE) * \
XVLIDAR_DETECTION_DEG) for k in range(XVLIDAR_SCAN_SIZE)]
self.half_canvas_pix = DISPLAY_CANVAS_SIZE_PIXELS / 2
scale = self.half_canvas_pix / float(XVLIDAR_MAX_SCAN_DIST_MM)
self.cos = [-cos(angle) * scale for angle in scan_angle_rad]
self.sin = [ sin(angle) * scale for angle in scan_angle_rad]
# Add scan lines to canvas, to be modified later
self.lines = [self.canvas.create_line(\
self.half_canvas_pix, \
self.half_canvas_pix, \
self.half_canvas_pix + self.sin[k] * XVLIDAR_MAX_SCAN_DIST_MM,\
self.half_canvas_pix + self.cos[k] * XVLIDAR_MAX_SCAN_DIST_MM)
for k in range(XVLIDAR_SCAN_SIZE)]
[self.canvas.itemconfig(line, fill=DISPLAY_SCAN_LINE_COLOR) for line in self.lines]
# Start a new thread and set a flag to let it know when we stop running
thread.start_new_thread( self.grab_scan, () )
self.running = True
class XVLidarPlotter(tk.Frame):
'''
XVLidarPlotter extends tk.Frame to plot Lidar scans.
'''
def __init__(self):
'''
Takes no args. Maybe we could specify colors, lidar params, etc.
'''
# Create the frame
tk.Frame.__init__(self, borderwidth = 4, relief = 'sunken')
self.master.geometry(str(DISPLAY_CANVAS_SIZE_PIXELS)+ "x" + str(DISPLAY_CANVAS_SIZE_PIXELS))
self.master.title('XV Lidar [ESC to quit]')
self.grid()
self.master.rowconfigure(0, weight = 1)
self.master.columnconfigure(0, weight = 1)
self.grid(sticky = tk.W+tk.E+tk.N+tk.S)
self.background = DISPLAY_CANVAS_COLOR
# Add a canvas for drawing
self.canvas = tk.Canvas(self, \
width = DISPLAY_CANVAS_SIZE_PIXELS, \
height = DISPLAY_CANVAS_SIZE_PIXELS,\
background = DISPLAY_CANVAS_COLOR)
self.canvas.grid(row = 0, column = 0,\
rowspan = 1, columnspan = 1,\
sticky = tk.W+tk.E+tk.N+tk.S)
# Set up a key event for exit on ESC
self.bind('<Key>', self._key)
# This call gives the frame focus so that it receives input
self.focus_set()
# No scanlines initially
self.lines = []
# Connect to the XVLidar
self.lidar = XVLidar(COM_PORT)
# No scan data to start
self.scandata = []
# Pre-compute some values useful for plotting
scan_angle_rad = [radians(-XVLIDAR_DETECTION_DEG/2 + (float(k)/XVLIDAR_SCAN_SIZE) * \
XVLIDAR_DETECTION_DEG) for k in range(XVLIDAR_SCAN_SIZE)]
self.half_canvas_pix = DISPLAY_CANVAS_SIZE_PIXELS / 2
scale = self.half_canvas_pix / float(XVLIDAR_MAX_SCAN_DIST_MM)
self.cos = [-cos(angle) * scale for angle in scan_angle_rad]
self.sin = [ sin(angle) * scale for angle in scan_angle_rad]
# Add scan lines to canvas, to be modified later
self.lines = [self.canvas.create_line(\
self.half_canvas_pix, \
self.half_canvas_pix, \
self.half_canvas_pix + self.sin[k] * XVLIDAR_MAX_SCAN_DIST_MM,\
self.half_canvas_pix + self.cos[k] * XVLIDAR_MAX_SCAN_DIST_MM)
for k in range(XVLIDAR_SCAN_SIZE)]
[self.canvas.itemconfig(line, fill=DISPLAY_SCAN_LINE_COLOR) for line in self.lines]
# Start a new thread and set a flag to let it know when we stop running
thread.start_new_thread( self.grab_scan, () )
self.running = True
# Runs on its own thread
def grab_scan(self):
while True:
# Lidar sends 360 (distance, quality) pairs, which may be empty on start
self.scandata = [pair[0] for pair in self.lidar.getScan()]
self.count += 1
if not self.running:
break
# yield to plotting thread
sleep(.0001)
def run(self):
'''
Call this when you're ready to run.
'''
# Record start time and initiate a count of scans for testing
self.count = 0
self.start_sec = time()
self.showcount = 0
# Start the recursive timer-task
plotter._task()
# Start the GUI
plotter.mainloop()
def destroy(self):
'''
Called automagically when user clicks X to close window.
'''
self._quit()
def _quit(self):
self.running = False
elapsed_sec = time() - self.start_sec
del self.lidar
exit(0)
def _key(self, event):
# Make sure the frame is receiving input!
self.focus_force()
if event.keysym == 'Escape':
self._quit()
def _task(self):
# Modify the displayed lines according to the current scan
[self.canvas.coords(self.lines[k],
self.half_canvas_pix, \
self.half_canvas_pix, \
self.half_canvas_pix + self.sin[k] * self.scandata[k],\
self.half_canvas_pix + self.cos[k] * self.scandata[k]) \
for k in range(len(self.scandata))]
# Reschedule this task immediately
self.after(1, self._task)
# Record another display for reporting performance
self.showcount += 1
