# fly ArduCopter in SITL # Flight mode switch positions are set-up in arducopter.param to be # switch 1 = Circle # switch 2 = Land # switch 3 = RTL # switch 4 = Auto # switch 5 = Loiter # switch 6 = Stabilize import util, pexpect, sys, time, math, shutil, os from common import * from pymavlink import mavutil, mavwp import random # get location of scripts testdir=os.path.dirname(os.path.realpath(__file__)) FRAME='+' TARGET='sitl' HOME=mavutil.location(-35.362938,149.165085,584,270) AVCHOME=mavutil.location(40.072842,-105.230575,1586,0) homeloc = None num_wp = 0 def hover(mavproxy, mav, hover_throttle=1450): mavproxy.send('rc 3 %u\n' % hover_throttle) return True def calibrate_level(mavproxy, mav): '''init the accelerometers''' print("Initialising accelerometers") mav.calibrate_level() mavproxy.expect(['APM: action received', 'COMMAND_ACK']) return True def arm_motors(mavproxy, mav): '''arm motors''' print("Arming motors") mavproxy.send('switch 6\n') # stabilize mode wait_mode(mav, 'STABILIZE') mavproxy.send('rc 3 1000\n') mavproxy.send('rc 4 2000\n') mavproxy.expect('APM: ARMING MOTORS') mavproxy.send('rc 4 1500\n') mav.motors_armed_wait() print("MOTORS ARMED OK") return True def disarm_motors(mavproxy, mav): '''disarm motors''' print("Disarming motors") mavproxy.send('switch 6\n') # stabilize mode wait_mode(mav, 'STABILIZE') mavproxy.send('rc 3 1000\n') mavproxy.send('rc 4 1000\n') mavproxy.expect('APM: DISARMING MOTORS') mavproxy.send('rc 4 1500\n') mav.motors_disarmed_wait() print("MOTORS DISARMED OK") return True def takeoff(mavproxy, mav, alt_min = 30, takeoff_throttle=1700): '''takeoff get to 30m altitude''' mavproxy.send('switch 6\n') # stabilize mode wait_mode(mav, 'STABILIZE') mavproxy.send('rc 3 %u\n' % takeoff_throttle) m = mav.recv_match(type='VFR_HUD', blocking=True) if (m.alt < alt_min): wait_altitude(mav, alt_min, (alt_min + 5)) hover(mavproxy, mav) print("TAKEOFF COMPLETE") return True # loiter - fly south west, then hold loiter within 5m position and altitude def loiter(mavproxy, mav, holdtime=15, maxaltchange=5, maxdistchange=5): '''hold loiter position''' mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') # first aim south east print("turn south east") mavproxy.send('rc 4 1580\n') if not wait_heading(mav, 170): return False mavproxy.send('rc 4 1500\n') #fly south east 50m mavproxy.send('rc 2 1100\n') if not wait_distance(mav, 50): return False mavproxy.send('rc 2 1500\n') # wait for copter to slow moving if not wait_groundspeed(mav, 0, 2): return False m = mav.recv_match(type='VFR_HUD', blocking=True) start_altitude = m.alt start = mav.location() tstart = time.time() tholdstart = time.time() print("Holding loiter at %u meters for %u seconds" % (start_altitude, holdtime)) while time.time() < tstart + holdtime: m = mav.recv_match(type='VFR_HUD', blocking=True) pos = mav.location() delta = get_distance(start, pos) print("Loiter Dist: %.2fm, alt:%u" % (delta, m.alt)) if math.fabs(m.alt - start_altitude) > maxaltchange: tholdstart = time.time() # this will cause this test to timeout and fails if delta > maxdistchange: tholdstart = time.time() # this will cause this test to timeout and fails if time.time() - tholdstart > holdtime: print("Loiter OK for %u seconds" % holdtime) return True print("Loiter FAILED") return False def change_alt(mavproxy, mav, alt_min, climb_throttle=1920, descend_throttle=1080): '''change altitude''' m = mav.recv_match(type='VFR_HUD', blocking=True) if(m.alt < alt_min): print("Rise to alt:%u from %u" % (alt_min, m.alt)) mavproxy.send('rc 3 %u\n' % climb_throttle) wait_altitude(mav, alt_min, (alt_min + 5)) else: print("Lower to alt:%u from %u" % (alt_min, m.alt)) mavproxy.send('rc 3 %u\n' % descend_throttle) wait_altitude(mav, (alt_min -5), alt_min) hover(mavproxy, mav) return True # fly a square in stabilize mode def fly_square(mavproxy, mav, side=50, timeout=120): '''fly a square, flying N then E''' tstart = time.time() failed = False # ensure all sticks in the middle mavproxy.send('rc 1 1500\n') mavproxy.send('rc 2 1500\n') mavproxy.send('rc 3 1500\n') mavproxy.send('rc 4 1500\n') # switch to loiter mode temporarily to stop us from rising mavproxy.send('switch 5\n') wait_mode(mav, 'LOITER') # first aim north print("turn right towards north") mavproxy.send('rc 4 1580\n') if not wait_heading(mav, 10): return False mavproxy.send('rc 4 1500\n') mav.recv_match(condition='RC_CHANNELS_RAW.chan4_raw==1500', blocking=True) # save bottom left corner of box as waypoint print("Save WP 1 & 2") save_wp(mavproxy, mav) # switch back to stabilize mode mavproxy.send('rc 3 1400\n') mavproxy.send('switch 6\n') wait_mode(mav, 'STABILIZE') # pitch forward to fly north print("Going north %u meters" % side) mavproxy.send('rc 2 1300\n') if not wait_distance(mav, side): failed = True mavproxy.send('rc 2 1500\n') # save top left corner of square as waypoint print("Save WP 3") save_wp(mavproxy, mav) # roll right to fly east print("Going east %u meters" % side) mavproxy.send('rc 1 1700\n') if not wait_distance(mav, side): failed = True mavproxy.send('rc 1 1500\n') # save top right corner of square as waypoint print("Save WP 4") save_wp(mavproxy, mav) # pitch back to fly south print("Going south %u meters" % side) mavproxy.send('rc 2 1700\n') if not wait_distance(mav, side): failed = True mavproxy.send('rc 2 1500\n') # save bottom right corner of square as waypoint print("Save WP 5") save_wp(mavproxy, mav) # roll left to fly west print("Going west %u meters" % side) mavproxy.send('rc 1 1300\n') if not wait_distance(mav, side): failed = True mavproxy.send('rc 1 1500\n') # save bottom left corner of square (should be near home) as waypoint print("Save WP 6") save_wp(mavproxy, mav) return not failed def fly_RTL(mavproxy, mav, side=60, timeout=250): '''Return, land''' print("# Enter RTL") mavproxy.send('switch 3\n') tstart = time.time() while time.time() < tstart + timeout: m = mav.recv_match(type='VFR_HUD', blocking=True) pos = mav.location() home_distance = get_distance(HOME, pos) print("Alt: %u HomeDistance: %.0f" % (m.alt, home_distance)) if(m.alt <= 1 and home_distance < 10): return True return False def fly_throttle_failsafe(mavproxy, mav, side=60, timeout=180): '''Fly east, Failsafe, return, land''' # switch to loiter mode temporarily to stop us from rising mavproxy.send('switch 5\n') wait_mode(mav, 'LOITER') # first aim east print("turn east") mavproxy.send('rc 4 1580\n') if not wait_heading(mav, 135): return False mavproxy.send('rc 4 1500\n') # switch to stabilize mode mavproxy.send('switch 6\n') wait_mode(mav, 'STABILIZE') hover(mavproxy, mav) failed = False # fly east 60 meters print("# Going forward %u meters" % side) mavproxy.send('rc 2 1350\n') if not wait_distance(mav, side, 5, 60): failed = True mavproxy.send('rc 2 1500\n') # pull throttle low print("# Enter Failsafe") mavproxy.send('rc 3 900\n') tstart = time.time() while time.time() < tstart + timeout: m = mav.recv_match(type='VFR_HUD', blocking=True) pos = mav.location() home_distance = get_distance(HOME, pos) print("Alt: %u HomeDistance: %.0f" % (m.alt, home_distance)) # check if we've reached home if m.alt <= 1 and home_distance < 10: # reduce throttle mavproxy.send('rc 3 1100\n') # switch back to stabilize mavproxy.send('switch 2\n') # land mode wait_mode(mav, 'LAND') mavproxy.send('switch 6\n') # stabilize mode wait_mode(mav, 'STABILIZE') print("Reached failsafe home OK") return True print("Failed to land on failsafe RTL - timed out after %u seconds" % timeout) # reduce throttle mavproxy.send('rc 3 1100\n') # switch back to stabilize mode mavproxy.send('switch 2\n') # land mode wait_mode(mav, 'LAND') mavproxy.send('switch 6\n') # stabilize mode wait_mode(mav, 'STABILIZE') return False def fly_battery_failsafe(mavproxy, mav, timeout=30): # assume failure success = False # switch to loiter mode so that we hold position mavproxy.send('switch 5\n') wait_mode(mav, 'LOITER') mavproxy.send("rc 3 1500\n") # enable battery failsafe mavproxy.send("param set FS_BATT_ENABLE 1\n") # trigger low voltage mavproxy.send('param set SIM_BATT_VOLTAGE 10\n') # wait for LAND mode if wait_mode(mav, 'LAND', timeout) == 'LAND': success = True # disable battery failsafe mavproxy.send('param set FS_BATT_ENABLE 0\n') # return status if success: print("Successfully entered LAND mode after battery failsafe") else: print("Failed to neter LAND mode after battery failsafe") return success # fly_stability_patch - fly south, then hold loiter within 5m position and altitude and reduce 1 motor to 60% efficiency def fly_stability_patch(mavproxy, mav, holdtime=30, maxaltchange=5, maxdistchange=10): '''hold loiter position''' mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') # first south print("turn south") mavproxy.send('rc 4 1580\n') if not wait_heading(mav, 180): return False mavproxy.send('rc 4 1500\n') #fly west 80m mavproxy.send('rc 2 1100\n') if not wait_distance(mav, 80): return False mavproxy.send('rc 2 1500\n') # wait for copter to slow moving if not wait_groundspeed(mav, 0, 2): return False m = mav.recv_match(type='VFR_HUD', blocking=True) start_altitude = m.alt start = mav.location() tstart = time.time() tholdstart = time.time() print("Holding loiter at %u meters for %u seconds" % (start_altitude, holdtime)) # cut motor 1 to 55% efficiency print("Cutting motor 1 to 55% efficiency") mavproxy.send('param set SIM_ENGINE_MUL 0.55\n') while time.time() < tstart + holdtime: m = mav.recv_match(type='VFR_HUD', blocking=True) pos = mav.location() delta = get_distance(start, pos) print("Loiter Dist: %.2fm, alt:%u" % (delta, m.alt)) if math.fabs(m.alt - start_altitude) > maxaltchange: tholdstart = time.time() # this will cause this test to timeout and fails if delta > maxdistchange: tholdstart = time.time() # this will cause this test to timeout and fails if time.time() - tholdstart > holdtime: print("Stability patch and Loiter OK for %u seconds" % holdtime) # restore motor 1 to 100% efficiency mavproxy.send('param set SIM_ENGINE_MUL 1.0\n') return True print("Stability Patch FAILED") # restore motor 1 to 100% efficiency mavproxy.send('param set SIM_ENGINE_MUL 1.0\n') return False # fly_fence_test - fly east until you hit the horizontal circular fence def fly_fence_test(mavproxy, mav, timeout=180): '''hold loiter position''' mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') # enable fence mavproxy.send('param set FENCE_ENABLE 1\n') # first east print("turn east") mavproxy.send('rc 4 1580\n') if not wait_heading(mav, 160): return False mavproxy.send('rc 4 1500\n') # fly forward (east) at least 20m pitching_forward = True mavproxy.send('rc 2 1100\n') if not wait_distance(mav, 20): return False # start timer tstart = time.time() while time.time() < tstart + timeout: m = mav.recv_match(type='VFR_HUD', blocking=True) pos = mav.location() home_distance = get_distance(HOME, pos) print("Alt: %u HomeDistance: %.0f" % (m.alt, home_distance)) # recenter pitch sticks once we reach home so we don't fly off again if pitching_forward and home_distance < 10 : pitching_forward = False mavproxy.send('rc 2 1500\n') # disable fence mavproxy.send('param set FENCE_ENABLE 0\n') if m.alt <= 1 and home_distance < 10: # reduce throttle mavproxy.send('rc 3 1000\n') # switch mode to stabilize mavproxy.send('switch 2\n') # land mode wait_mode(mav, 'LAND') mavproxy.send('switch 6\n') # stabilize mode wait_mode(mav, 'STABILIZE') print("Reached home OK") return True # disable fence mavproxy.send('param set FENCE_ENABLE 0\n') # reduce throttle mavproxy.send('rc 3 1000\n') # switch mode to stabilize mavproxy.send('switch 2\n') # land mode wait_mode(mav, 'LAND') mavproxy.send('switch 6\n') # stabilize mode wait_mode(mav, 'STABILIZE') print("Fence test failed to reach home - timed out after %u seconds" % timeout) return False def show_gps_and_sim_positions(mavproxy, on_off): if on_off == True: # turn on simulator display of gps and actual position mavproxy.send('map set showgpspos 1\n') mavproxy.send('map set showsimpos 1\n') else: # turn off simulator display of gps and actual position mavproxy.send('map set showgpspos 0\n') mavproxy.send('map set showsimpos 0\n') # fly_gps_glitch_loiter_test - fly south east in loiter and test reaction to gps glitch def fly_gps_glitch_loiter_test(mavproxy, mav, timeout=30, max_distance=10): '''hold loiter position''' mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') # turn on simulator display of gps and actual position show_gps_and_sim_positions(mavproxy, True) # set-up gps glitch array glitch_lat = [0.0002996,0.0006958,0.0009431,0.0009991,0.0009444,0.0007716,0.0006221] glitch_lon = [0.0000717,0.0000912,0.0002761,0.0002626,0.0002807,0.0002049,0.0001304] glitch_num = len(glitch_lat) print("GPS Glitches:") for i in range(1,glitch_num): print("glitch %d %.7f %.7f" % (i,glitch_lat[i],glitch_lon[i])) # turn south east print("turn south east") mavproxy.send('rc 4 1580\n') if not wait_heading(mav, 150): show_gps_and_sim_positions(mavproxy, False) return False mavproxy.send('rc 4 1500\n') # fly forward (south east) at least 60m mavproxy.send('rc 2 1100\n') if not wait_distance(mav, 60): show_gps_and_sim_positions(mavproxy, False) return False mavproxy.send('rc 2 1500\n') # wait for copter to slow down if not wait_groundspeed(mav, 0, 2): show_gps_and_sim_positions(mavproxy, False) return False # record time and position tstart = time.time() start_pos = sim_location(mav) # initialise current glitch glitch_current = 0; print("Apply first glitch") mavproxy.send('param set SIM_GPS_GLITCH_X %.7f\n' % glitch_lat[glitch_current]) mavproxy.send('param set SIM_GPS_GLITCH_Y %.7f\n' % glitch_lon[glitch_current]) # record position for 30 seconds while time.time() < tstart + timeout: time_in_sec = int(time.time() - tstart); if time_in_sec > glitch_current and glitch_current != -1: glitch_current = time_in_sec # turn off glitching if we've reached the end of the glitch list if glitch_current >= glitch_num: glitch_current = -1 mavproxy.send('param set SIM_GPS_GLITCH_X 0\n') mavproxy.send('param set SIM_GPS_GLITCH_Y 0\n') else: #move onto the next glitch mavproxy.send('param set SIM_GPS_GLITCH_X %.7f\n' % glitch_lat[glitch_current]) mavproxy.send('param set SIM_GPS_GLITCH_Y %.7f\n' % glitch_lon[glitch_current]) m = mav.recv_match(type='VFR_HUD', blocking=True) curr_pos = sim_location(mav) moved_distance = get_distance(curr_pos, start_pos) print("Alt: %u Moved: %.0f" % (m.alt, moved_distance)) if moved_distance > max_distance: print("Moved over %u meters, Failed!" % max_distance) # disable gps glitch mavproxy.send('param set SIM_GPS_GLITCH_X 0\n') mavproxy.send('param set SIM_GPS_GLITCH_Y 0\n') show_gps_and_sim_positions(mavproxy, False) return False # disable gps glitch if glitch_current != -1: glitch_current = -1 mavproxy.send('param set SIM_GPS_GLITCH_X 0\n') mavproxy.send('param set SIM_GPS_GLITCH_Y 0\n') show_gps_and_sim_positions(mavproxy, False) # if we've gotten this far then we've succeeded print("GPS glitch test passed! stayed within %u meters for %u seconds" % (max_distance, timeout)) return True # fly_gps_glitch_auto_test - fly mission and test reaction to gps glitch def fly_gps_glitch_auto_test(mavproxy, mav, timeout=30, max_distance=100): # set-up gps glitch array glitch_lat = [0.0002996,0.0006958,0.0009431,0.0009991,0.0009444,0.0007716,0.0006221] glitch_lon = [0.0000717,0.0000912,0.0002761,0.0002626,0.0002807,0.0002049,0.0001304] glitch_num = len(glitch_lat) print("GPS Glitches:") for i in range(1,glitch_num): print("glitch %d %.7f %.7f" % (i,glitch_lat[i],glitch_lon[i])) # Fly mission #1 print("# Upload copter_glitch_mission") if not upload_mission_from_file(mavproxy, mav, os.path.join(testdir, "copter_glitch_mission.txt")): print("upload copter_glitch_mission.txt failed") return False # this grabs our mission count if not load_mission_from_file(mavproxy, mav, os.path.join(testdir, "copter_glitch_mission.txt")): print("load copter_glitch_mission failed") return False # turn on simulator display of gps and actual position show_gps_and_sim_positions(mavproxy, True) # load the waypoint count global homeloc global num_wp print("test: Fly a mission from 1 to %u" % num_wp) mavproxy.send('wp set 1\n') # switch into AUTO mode and raise throttle mavproxy.send('switch 4\n') # auto mode wait_mode(mav, 'AUTO') mavproxy.send('rc 3 1500\n') # wait until 100m from home if not wait_distance(mav, 100, 5, 60): show_gps_and_sim_positions(mavproxy, False) return False # record time and position tstart = time.time() start_pos = sim_location(mav) # initialise current glitch glitch_current = 0; print("Apply first glitch") mavproxy.send('param set SIM_GPS_GLITCH_X %.7f\n' % glitch_lat[glitch_current]) mavproxy.send('param set SIM_GPS_GLITCH_Y %.7f\n' % glitch_lon[glitch_current]) # record position for 30 seconds while glitch_current < glitch_num: time_in_sec = int(time.time() - tstart); if time_in_sec > glitch_current and glitch_current != -1: glitch_current = time_in_sec # apply next glitch if glitch_current < glitch_num: mavproxy.send('param set SIM_GPS_GLITCH_X %.7f\n' % glitch_lat[glitch_current]) mavproxy.send('param set SIM_GPS_GLITCH_Y %.7f\n' % glitch_lon[glitch_current]) # turn off glitching mavproxy.send('param set SIM_GPS_GLITCH_X 0\n') mavproxy.send('param set SIM_GPS_GLITCH_Y 0\n') # continue with the mission ret = wait_waypoint(mav, 0, num_wp, timeout=500, mode='AUTO') # turn off simulator display of gps and actual position show_gps_and_sim_positions(mavproxy, False) print("GPS Glitch test Auto completed: passed=%s" % ret) return ret #fly_simple - assumes the simple bearing is initialised to be directly north # flies a box with 100m west, 15 seconds north, 50 seconds east, 15 seconds south def fly_simple(mavproxy, mav, side=50, timeout=120): failed = False # hold position in loiter mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') #set SIMPLE mode for all flight modes mavproxy.send('param set SIMPLE 63\n') # switch to stabilize mode mavproxy.send('switch 6\n') wait_mode(mav, 'STABILIZE') mavproxy.send('rc 3 1400\n') # fly south 50m print("# Flying south %u meters" % side) mavproxy.send('rc 1 1300\n') if not wait_distance(mav, side, 5, 60): failed = True mavproxy.send('rc 1 1500\n') # fly west 8 seconds print("# Flying west for 8 seconds") mavproxy.send('rc 2 1300\n') tstart = time.time() while time.time() < (tstart + 8): m = mav.recv_match(type='VFR_HUD', blocking=True) delta = (time.time() - tstart) #print("%u" % delta) mavproxy.send('rc 2 1500\n') # fly north 25 meters print("# Flying north %u meters" % (side/2.0)) mavproxy.send('rc 1 1700\n') if not wait_distance(mav, side/2, 5, 60): failed = True mavproxy.send('rc 1 1500\n') # fly east 8 seconds print("# Flying east for 8 seconds") mavproxy.send('rc 2 1700\n') tstart = time.time() while time.time() < (tstart + 8): m = mav.recv_match(type='VFR_HUD', blocking=True) delta = (time.time() - tstart) #print("%u" % delta) mavproxy.send('rc 2 1500\n') #restore to default mavproxy.send('param set SIMPLE 0\n') #hover in place hover(mavproxy, mav) return not failed #fly_super_simple - flies a circle around home for 45 seconds def fly_super_simple(mavproxy, mav, timeout=45): failed = False # hold position in loiter mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') # fly forward 20m print("# Flying forward 20 meters") mavproxy.send('rc 2 1300\n') if not wait_distance(mav, 20, 5, 60): failed = True mavproxy.send('rc 2 1500\n') #set SUPER SIMPLE mode for all flight modes mavproxy.send('param set SUPER_SIMPLE 63\n') # switch to stabilize mode mavproxy.send('switch 6\n') wait_mode(mav, 'STABILIZE') mavproxy.send('rc 3 1400\n') # start copter yawing slowly mavproxy.send('rc 4 1550\n') # roll left for timeout seconds print("# rolling left from pilot's point of view for %u seconds" % timeout) mavproxy.send('rc 1 1300\n') tstart = time.time() while time.time() < (tstart + timeout): m = mav.recv_match(type='VFR_HUD', blocking=True) delta = (time.time() - tstart) # stop rolling and yawing mavproxy.send('rc 1 1500\n') mavproxy.send('rc 4 1500\n') #restore simple mode parameters to default mavproxy.send('param set SUPER_SIMPLE 0\n') #hover in place hover(mavproxy, mav) return not failed #fly_circle - flies a circle with 20m radius def fly_circle(mavproxy, mav, maxaltchange=10, holdtime=36): # hold position in loiter mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') # face west print("turn west") mavproxy.send('rc 4 1580\n') if not wait_heading(mav, 270): return False mavproxy.send('rc 4 1500\n') #set CIRCLE radius mavproxy.send('param set CIRCLE_RADIUS 30\n') # fly forward (east) at least 100m mavproxy.send('rc 2 1100\n') if not wait_distance(mav, 100): return False # return pitch stick back to middle mavproxy.send('rc 2 1500\n') # set CIRCLE mode mavproxy.send('switch 1\n') # circle mode wait_mode(mav, 'CIRCLE') # wait m = mav.recv_match(type='VFR_HUD', blocking=True) start_altitude = m.alt tstart = time.time() tholdstart = time.time() print("Circle at %u meters for %u seconds" % (start_altitude, holdtime)) while time.time() < tstart + holdtime: m = mav.recv_match(type='VFR_HUD', blocking=True) print("heading %u" % m.heading) print("CIRCLE OK for %u seconds" % holdtime) return True def land(mavproxy, mav, timeout=60): '''land the quad''' print("STARTING LANDING") mavproxy.send('switch 2\n') # land mode wait_mode(mav, 'LAND') print("Entered Landing Mode") ret = wait_altitude(mav, -5, 1) print("LANDING: ok= %s" % ret) return ret def fly_mission(mavproxy, mav, height_accuracy=-1, target_altitude=None): '''fly a mission from a file''' global homeloc global num_wp print("test: Fly a mission from 1 to %u" % num_wp) mavproxy.send('wp set 1\n') mavproxy.send('switch 4\n') # auto mode wait_mode(mav, 'AUTO') #wait_altitude(mav, 30, 40) ret = wait_waypoint(mav, 0, num_wp, timeout=500, mode='AUTO') print("test: MISSION COMPLETE: passed=%s" % ret) # wait here until ready mavproxy.send('switch 5\n') # loiter mode wait_mode(mav, 'LOITER') return ret def load_mission_from_file(mavproxy, mav, filename): '''load a mission from a file''' global num_wp wploader = mavwp.MAVWPLoader() wploader.load(filename) num_wp = wploader.count() print("loaded mission with %u waypoints" % num_wp) return True def upload_mission_from_file(mavproxy, mav, filename): '''Upload a mission from a file to APM''' global num_wp mavproxy.send('wp load %s\n' % filename) mavproxy.expect('flight plan received') mavproxy.send('wp list\n') mavproxy.expect('Requesting [0-9]+ waypoints') return True def save_mission_to_file(mavproxy, mav, filename): global num_wp mavproxy.send('wp save %s\n' % filename) mavproxy.expect('Saved ([0-9]+) waypoints') num_wp = int(mavproxy.match.group(1)) print("num_wp: %d" % num_wp) return True def setup_rc(mavproxy): '''setup RC override control''' for chan in range(1,9): mavproxy.send('rc %u 1500\n' % chan) # zero throttle mavproxy.send('rc 3 1000\n') def fly_ArduCopter(viewerip=None, map=False): '''fly ArduCopter in SIL you can pass viewerip as an IP address to optionally send fg and mavproxy packets too for local viewing of the flight in real time ''' global homeloc if TARGET != 'sitl': util.build_SIL('ArduCopter', target=TARGET) sim_cmd = util.reltopdir('Tools/autotest/pysim/sim_multicopter.py') + ' --frame=%s --rate=400 --home=%f,%f,%u,%u' % ( FRAME, HOME.lat, HOME.lng, HOME.alt, HOME.heading) sim_cmd += ' --wind=6,45,.3' if viewerip: sim_cmd += ' --fgout=%s:5503' % viewerip sil = util.start_SIL('ArduCopter', wipe=True) mavproxy = util.start_MAVProxy_SIL('ArduCopter', options='--sitl=127.0.0.1:5501 --out=127.0.0.1:19550 --quadcopter') mavproxy.expect('Received [0-9]+ parameters') # setup test parameters mavproxy.send('param set SYSID_THISMAV %u\n' % random.randint(100, 200)) mavproxy.send("param load %s/ArduCopter.parm\n" % testdir) mavproxy.expect('Loaded [0-9]+ parameters') # reboot with new parameters util.pexpect_close(mavproxy) util.pexpect_close(sil) sil = util.start_SIL('ArduCopter', height=HOME.alt) sim = pexpect.spawn(sim_cmd, logfile=sys.stdout, timeout=10) sim.delaybeforesend = 0 util.pexpect_autoclose(sim) options = '--sitl=127.0.0.1:5501 --out=127.0.0.1:19550 --quadcopter --streamrate=5' if viewerip: options += ' --out=%s:14550' % viewerip if map: options += ' --map' mavproxy = util.start_MAVProxy_SIL('ArduCopter', options=options) mavproxy.expect('Logging to (\S+)') logfile = mavproxy.match.group(1) print("LOGFILE %s" % logfile) buildlog = util.reltopdir("../buildlogs/ArduCopter-test.tlog") print("buildlog=%s" % buildlog) if os.path.exists(buildlog): os.unlink(buildlog) try: os.link(logfile, buildlog) except Exception: pass # the received parameters can come before or after the ready to fly message mavproxy.expect(['Received [0-9]+ parameters', 'Ready to FLY']) mavproxy.expect(['Received [0-9]+ parameters', 'Ready to FLY']) util.expect_setup_callback(mavproxy, expect_callback) expect_list_clear() expect_list_extend([sim, sil, mavproxy]) # get a mavlink connection going try: mav = mavutil.mavlink_connection('127.0.0.1:19550', robust_parsing=True) except Exception, msg: print("Failed to start mavlink connection on 127.0.0.1:19550" % msg) raise mav.message_hooks.append(message_hook) mav.idle_hooks.append(idle_hook) failed = False e = 'None' try: mav.wait_heartbeat() setup_rc(mavproxy) homeloc = mav.location() print("# Calibrate level") if not calibrate_level(mavproxy, mav): print("calibrate_level failed") failed = True # Arm print("# Arm motors") if not arm_motors(mavproxy, mav): print("arm_motors failed") failed = True print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Fly a square in Stabilize mode print("#") print("########## Fly a square and save WPs with CH7 switch ##########") print("#") if not fly_square(mavproxy, mav): print("fly_square failed") failed = True print("# Land") if not land(mavproxy, mav): print("land failed") failed = True print("Save landing WP") save_wp(mavproxy, mav) # save the stored mission to file print("# Save out the CH7 mission to file") if not save_mission_to_file(mavproxy, mav, os.path.join(testdir, "ch7_mission.txt")): print("save_mission_to_file failed") failed = True # fly the stored mission print("# Fly CH7 saved mission") if not fly_mission(mavproxy, mav,height_accuracy = 0.5, target_altitude=10): print("fly_mission failed") failed = True # Throttle Failsafe print("#") print("########## Test Failsafe ##########") print("#") if not fly_throttle_failsafe(mavproxy, mav): print("FS failed") failed = True # Takeoff print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Battery failsafe if not fly_battery_failsafe(mavproxy, mav): print("battery failsafe failed") failed = True # Takeoff print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Stability patch print("#") print("########## Test Stability Patch ##########") print("#") if not fly_stability_patch(mavproxy, mav, 30): print("Stability Patch failed") failed = True # RTL print("# RTL #") if not fly_RTL(mavproxy, mav): print("RTL failed") failed = True # Takeoff print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Fence test print("#") print("########## Test Horizontal Fence ##########") print("#") if not fly_fence_test(mavproxy, mav, 180): print("Fence test failed") failed = True # Takeoff print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Fly GPS Glitch Loiter test print("# GPS Glitch Loiter Test") if not fly_gps_glitch_loiter_test(mavproxy, mav): print("failed GPS glitch Loiter test") failed = True # RTL after GPS Glitch Loiter test print("# RTL #") if not fly_RTL(mavproxy, mav): print("RTL failed") failed = True # Fly GPS Glitch test in auto mode print("# GPS Glitch Auto Test") if not fly_gps_glitch_auto_test(mavproxy, mav): print("failed GPS glitch Auto test") failed = True # take-off ahead of next test print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Loiter for 15 seconds print("#") print("########## Test Loiter for 15 seconds ##########") print("#") if not loiter(mavproxy, mav): print("loiter failed") failed = True # Loiter Climb print("#") print("# Loiter - climb to 40m") print("#") if not change_alt(mavproxy, mav, 40): print("change_alt failed") failed = True # Loiter Descend print("#") print("# Loiter - descend to 20m") print("#") if not change_alt(mavproxy, mav, 20): print("change_alt failed") failed = True if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # RTL print("#") print("########## Test RTL ##########") print("#") if not fly_RTL(mavproxy, mav): print("RTL failed") failed = True # Takeoff print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Simple mode print("# Fly in SIMPLE mode") if not fly_simple(mavproxy, mav): print("fly_simple failed") failed = True # RTL print("#") print("########## Test RTL ##########") print("#") if not fly_RTL(mavproxy, mav): print("RTL failed") failed = True # Takeoff print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Fly a circle in super simple mode print("# Fly a circle in SUPER SIMPLE mode") if not fly_super_simple(mavproxy, mav): print("fly super simple failed") failed = True # RTL print("# RTL #") if not fly_RTL(mavproxy, mav): print("RTL failed") failed = True # Takeoff print("# Takeoff") if not takeoff(mavproxy, mav, 10): print("takeoff failed") failed = True # Circle mode print("# Fly CIRCLE mode") if not fly_circle(mavproxy, mav): print("fly_circle failed") failed = True # RTL print("#") print("########## Test RTL ##########") print("#") if not fly_RTL(mavproxy, mav): print("RTL failed") failed = True # Fly mission #1 print("# Upload copter_mission") if not upload_mission_from_file(mavproxy, mav, os.path.join(testdir, "copter_mission.txt")): print("upload_mission_from_file failed") failed = True # this grabs our mission count print("# store copter_mission locally") if not load_mission_from_file(mavproxy, mav, os.path.join(testdir, "copter_mission.txt")): print("load_mission_from_file failed") failed = True print("# Fly mission 1") if not fly_mission(mavproxy, mav,height_accuracy = 0.5, target_altitude=10): print("fly_mission failed") failed = True else: print("Flew mission 1 OK") #mission includes LAND at end so should be ok to disamr print("# disarm motors") if not disarm_motors(mavproxy, mav): print("disarm_motors failed") failed = True if not log_download(mavproxy, mav, util.reltopdir("../buildlogs/ArduCopter-log.bin")): print("Failed log download") failed = True except pexpect.TIMEOUT, e: failed = True mav.close() util.pexpect_close(mavproxy) util.pexpect_close(sil) util.pexpect_close(sim) if os.path.exists('ArduCopter-valgrind.log'): os.chmod('ArduCopter-valgrind.log', 0644) shutil.copy("ArduCopter-valgrind.log", util.reltopdir("../buildlogs/ArduCopter-valgrind.log")) if failed: print("FAILED: %s" % e) return False return True def fly_CopterAVC(viewerip=None, map=False): '''fly ArduCopter in SIL for AVC2013 mission ''' global homeloc if TARGET != 'sitl': util.build_SIL('ArduCopter', target=TARGET) sim_cmd = util.reltopdir('Tools/autotest/pysim/sim_multicopter.py') + ' --frame=%s --rate=400 --home=%f,%f,%u,%u' % ( FRAME, AVCHOME.lat, AVCHOME.lng, AVCHOME.alt, AVCHOME.heading) if viewerip: sim_cmd += ' --fgout=%s:5503' % viewerip sil = util.start_SIL('ArduCopter', wipe=True) mavproxy = util.start_MAVProxy_SIL('ArduCopter', options='--sitl=127.0.0.1:5501 --out=127.0.0.1:19550 --quadcopter') mavproxy.expect('Received [0-9]+ parameters') # setup test parameters mavproxy.send('param set SYSID_THISMAV %u\n' % random.randint(100, 200)) mavproxy.send("param load %s/CopterAVC.parm\n" % testdir) mavproxy.expect('Loaded [0-9]+ parameters') # reboot with new parameters util.pexpect_close(mavproxy) util.pexpect_close(sil) sil = util.start_SIL('ArduCopter', height=HOME.alt) sim = pexpect.spawn(sim_cmd, logfile=sys.stdout, timeout=10) sim.delaybeforesend = 0 util.pexpect_autoclose(sim) options = '--sitl=127.0.0.1:5501 --out=127.0.0.1:19550 --quadcopter --streamrate=5' if viewerip: options += ' --out=%s:14550' % viewerip if map: options += ' --map' mavproxy = util.start_MAVProxy_SIL('ArduCopter', options=options) mavproxy.expect('Logging to (\S+)') logfile = mavproxy.match.group(1) print("LOGFILE %s" % logfile) buildlog = util.reltopdir("../buildlogs/CopterAVC-test.tlog") print("buildlog=%s" % buildlog) if os.path.exists(buildlog): os.unlink(buildlog) try: os.link(logfile, buildlog) except Exception: pass # the received parameters can come before or after the ready to fly message mavproxy.expect(['Received [0-9]+ parameters', 'Ready to FLY']) mavproxy.expect(['Received [0-9]+ parameters', 'Ready to FLY']) util.expect_setup_callback(mavproxy, expect_callback) expect_list_clear() expect_list_extend([sim, sil, mavproxy]) if map: mavproxy.send('map icon 40.072467969730496 -105.2314389590174\n') mavproxy.send('map icon 40.072600990533829 -105.23146100342274\n') # get a mavlink connection going try: mav = mavutil.mavlink_connection('127.0.0.1:19550', robust_parsing=True) except Exception, msg: print("Failed to start mavlink connection on 127.0.0.1:19550" % msg) raise mav.message_hooks.append(message_hook) mav.idle_hooks.append(idle_hook) failed = False e = 'None' try: mav.wait_heartbeat() setup_rc(mavproxy) homeloc = mav.location() print("# Calibrate level") if not calibrate_level(mavproxy, mav): print("calibrate_level failed") failed = True # Arm print("# Arm motors") if not arm_motors(mavproxy, mav): print("arm_motors failed") failed = True # Fly mission #1 print("# Upload AVC mission") if not upload_mission_from_file(mavproxy, mav, os.path.join(testdir, "AVC2013.txt")): print("upload_mission_from_file failed") failed = True # this grabs our mission count print("# store mission1 locally") if not load_mission_from_file(mavproxy, mav, os.path.join(testdir, "AVC2013.txt")): print("load_mission_from_file failed") failed = True print("# raising throttle") mavproxy.send('rc 3 1300\n') print("# Fly mission 1") if not fly_mission(mavproxy, mav,height_accuracy = 0.5, target_altitude=10): print("fly_mission failed") failed = True else: print("Flew mission 1 OK") print("# lowering throttle") mavproxy.send('rc 3 1000\n') #mission includes LAND at end so should be ok to disamr print("# disarm motors") if not disarm_motors(mavproxy, mav): print("disarm_motors failed") failed = True if not log_download(mavproxy, mav, util.reltopdir("../buildlogs/CopterAVC-log.bin")): print("Failed log download") failed = True except pexpect.TIMEOUT, e: failed = True mav.close() util.pexpect_close(mavproxy) util.pexpect_close(sil) util.pexpect_close(sim) if failed: print("FAILED: %s" % e) return False return True