ardupilot/Tools/autotest/pysim/sim_rover.py

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#!/usr/bin/env python
'''
simple rover simulator
'''
from rover import Rover
import util, time, os, sys, math
import socket, struct
import select, errno
sys.path.insert(0, os.path.join(os.path.dirname(os.path.realpath(__file__)), '..', '..', '..', '..', 'mavlink', 'pymavlink'))
def sim_send(a):
'''send flight information to mavproxy'''
from math import degrees
earth_rates = util.BodyRatesToEarthRates(a.dcm, a.gyro)
(roll, pitch, yaw) = a.dcm.to_euler()
buf = struct.pack('<17dI',
a.latitude, a.longitude, a.altitude, degrees(yaw),
a.velocity.x, a.velocity.y, a.velocity.z,
a.accelerometer.x, a.accelerometer.y, a.accelerometer.z,
degrees(earth_rates.x), degrees(earth_rates.y), degrees(earth_rates.z),
degrees(roll), degrees(pitch), degrees(yaw),
math.sqrt(a.velocity.x*a.velocity.x + a.velocity.y*a.velocity.y),
0x4c56414f)
try:
sim_out.send(buf)
except socket.error as e:
if not e.errno in [ errno.ECONNREFUSED ]:
raise
def sim_recv(state):
'''receive control information from SITL'''
try:
buf = sim_in.recv(28)
except socket.error as e:
if not e.errno in [ errno.EAGAIN, errno.EWOULDBLOCK ]:
raise
return
if len(buf) != 28:
print('len=%u' % len(buf))
return
control = list(struct.unpack('<14H', buf))
pwm = control[0:11]
# map steering and throttle to -1/1
state.steering = (pwm[0]-1500)/500.0
state.throttle = (pwm[2]-1500)/500.0
# print("steering=%f throttle=%f pwm=%s" % (state.steering, state.throttle, str(pwm)))
def interpret_address(addrstr):
'''interpret a IP:port string'''
a = addrstr.split(':')
a[1] = int(a[1])
return tuple(a)
class ControlState:
def __init__(self):
# steering from -1 to 1, where -1 is left, 1 is right
self.steering = 0
# throttle from -1 to 1, where -1 is full reverse, 1 is full forward
self.throttle = 0
##################
# main program
from optparse import OptionParser
parser = OptionParser("sim_rover.py [options]")
parser.add_option("--simin", dest="simin", help="SIM input (IP:port)", default="127.0.0.1:5502")
parser.add_option("--simout", dest="simout", help="SIM output (IP:port)", default="127.0.0.1:5501")
parser.add_option("--home", dest="home", type='string', default=None, help="home lat,lng,alt,hdg (required)")
parser.add_option("--rate", dest="rate", type='int', help="SIM update rate", default=100)
parser.add_option("--skid-steering", action='store_true', default=False, help="Use skid steering")
(opts, args) = parser.parse_args()
for m in [ 'home' ]:
if not opts.__dict__[m]:
print("Missing required option '%s'" % m)
parser.print_help()
sys.exit(1)
# UDP socket addresses
sim_out_address = interpret_address(opts.simout)
sim_in_address = interpret_address(opts.simin)
# setup input from SITL
sim_in = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
sim_in.bind(sim_in_address)
sim_in.setblocking(0)
# setup output to SITL
sim_out = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
sim_out.connect(sim_out_address)
sim_out.setblocking(0)
# create the quadcopter model
a = Rover(skid_steering=opts.skid_steering)
# initial controls state
state = ControlState()
# parse home
v = opts.home.split(',')
if len(v) != 4:
print("home should be lat,lng,alt,hdg")
sys.exit(1)
a.home_latitude = float(v[0])
a.home_longitude = float(v[1])
a.home_altitude = float(v[2])
a.altitude = a.home_altitude
a.yaw = float(v[3])
a.latitude = a.home_latitude
a.longitude = a.home_longitude
print("Starting at lat=%f lon=%f alt=%f heading=%.1f" % (
a.home_latitude,
a.home_longitude,
a.altitude,
a.yaw))
frame_time = 1.0/opts.rate
sleep_overhead = 0
while True:
frame_start = time.time()
sim_recv(state)
a.update(state)
sim_send(a)
t = time.time()
frame_end = time.time()
if frame_end - frame_start < frame_time:
dt = frame_time - (frame_end - frame_start)
dt -= sleep_overhead
if dt > 0:
time.sleep(dt)
sleep_overhead = 0.99*sleep_overhead + 0.01*(time.time() - frame_end)