-- Adds a smart failsafe that accounts for how far the plane is from home -- the average battery consumption, and the wind to decide when to failsafe -- -- CAUTION: This script only works for Plane -- store the batt info as { instance, filtered, capacity, margin_mah } -- instance: the battery monitor instance (zero indexed) -- filtered: internal variable for current draw -- capacity: internal variable populated from battery monitor capacity param -- margin_mah: the mah to be remaining when you reach home and use the time margin, note that this is on top of CRT_MAH local batt_info = { {0, 0, 0, 0}, -- main battery -- add more batteries to monitor here } local margin = 30 -- margin in seconds of flight time that should remain once we have reached local time_SF = 1 -- the return time safety factor, 1.1 gives 10% extra time for return flight local filter = 0.9 -- filter gain local min_flying_time = 30 -- seconds, must have been flying in a none Qmode above the min alt for this long before script will start sampling current local print_time = 15 -- seconds between update prints (set to zero to disable) local alt_min = 0 -- the minimum altitude above home the script will start working at, zero disables -- if true current draw is normalized with dynamic pressure -- this gives better prediction of current draws at other airspeeds -- airspeed sensor recommended local airspeed_normalize = false -- hard code wind to match SITL -- should get exact return time estimates < +- 5 seconds local SITL_wind = false -- Read in required params local value = param:get('TRIM_ARSPD_CM') if value then air_speed = value / 100 else error('LUA: get TRIM_ARSPD_CM failed') end local value = param:get('ARSPD_FBW_MIN') if value then min_air_speed = value else error('LUA: get ARSPD_FBW_MIN failed') end local value = param:get('MIN_GNDSPD_CM') if value then min_ground_speed = value / 100 else error('LUA: get MIN_GNDSPD_CM failed') end local value = param:get('LIM_ROLL_CD') if value then max_bank_angle = value / 100 else error('LUA: get LIM_ROLL_CD failed') end -- https://en.wikipedia.org/wiki/Standard_rate_turn#Radius_of_turn_formula -- the radius is equal to the circumference per 1 radian local turn_rad = (air_speed^2) / (9.81 * math.tan(math.rad(max_bank_angle))) -- Read the radius we expect to circle at when we get home local home_reached_rad local value = param:get('RTL_RADIUS') if value then value = math.abs(value) if value > 0 then home_reached_rad = math.abs(value) * 2 else value = param:get('WP_LOITER_RAD') if value then home_reached_rad = math.abs(value) * 2 else error('LUA: get WP_LOITER_RAD failed') end end else error('LUA: get RTL_RADIUS failed') end -- internal global variables local return_start local return_distance local return_amps local trigger_instance = batt_info[1][1] local last_print = 0 local timer_start_time = 0 local timer_active = true -- calculates the amount of time it will take for the vehicle to return home -- returns 0 if there is no position, wind or home available -- returns a negative number if it will take excessively long time, or is impossible -- otherwise returns the time in seconds to get back local function time_to_home() local home = ahrs:get_home() local position = ahrs:get_position() local wind = ahrs:wind_estimate() if home and position and wind then local bearing = position:get_bearing(home) -- wind is in NED, convert for readability local wind_north = wind:x() local wind_east = wind:y() -- hard code wind for testing if SITL_wind then -- only safe to read from params at a high rate because we are in SITL -- don't do this on a real vehicle wind_speed = param:get('SIM_WIND_SPD') wind_dir = param:get('SIM_WIND_DIR') if wind_speed and wind_dir then wind_dir = math.rad(wind_dir) wind_north = -math.cos(wind_dir) * wind_speed wind_east = -math.sin(wind_dir) * wind_speed else error('Could not read SITL wind') end end --gcs:send_text(0, string.format("Wind: north %0.2f, east %0.2f",wind_north,wind_east)) -- rotate the wind vector inline with the home bearing local tail_wind = math.sin(bearing) * wind_east + math.cos(bearing) * wind_north local cross_wind = math.cos(bearing) * wind_east + math.sin(bearing) * wind_north -- left to right -- we can't get home if math.abs(cross_wind) > air_speed then return -1, air_speed -- FIXME: this should really be infinity end -- calculate the crab angle required to cancel out the cross wind local crab_angle = math.asin(-cross_wind / air_speed) -- the resulting speed in the desired direction local home_airspeed = air_speed * math.cos(crab_angle) local effective_speed = home_airspeed + tail_wind -- Estimate the extra distance required to turn local yaw = ahrs:get_yaw() -- this is the estimated angle we have to turn to be at the home bearing and crab angle local turn_angle_rad = bearing - crab_angle - yaw -- wrap to +- PI if turn_angle_rad < math.rad(-180) then turn_angle_rad = turn_angle_rad + math.rad(360) elseif turn_angle_rad > math.rad(180) then turn_angle_rad = turn_angle_rad - math.rad(360) end --gcs:send_text(0, "turn " .. tostring(math.deg(turn_angle_rad)) .. " deg") -- Take into account min ground speed and resulting increased RTL airspeed local return_air_speed = air_speed if min_ground_speed > 0 and effective_speed < min_ground_speed then -- we travel home at the min ground speed effective_speed = min_ground_speed -- work out the resulting airspeed return_air_speed = math.sqrt((effective_speed-tail_wind)^2 + cross_wind^2) end -- distance to travel over ground speed + turn circumference over airspeed return (position:get_distance(home) / effective_speed) + (math.abs(turn_angle_rad*turn_rad) / air_speed), return_air_speed end return 0, air_speed -- nothing useful available end -- idle function function idle() -- if disarmed and not flying reset for a potential second trigger if not arming:is_armed() and not vehicle:get_likely_flying() then return update, 100 end return idle, 1000 end -- time margin update function function margin_update() if not vehicle:get_likely_flying() then -- no longer flying, idle function return idle, 10000 end -- display the remaining battery capacity on the triggered monitor local capacity = battery:pack_capacity_mah(trigger_instance) local consumed = battery:consumed_mah(trigger_instance) if capacity and consumed then gcs:send_text(0, string.format("Failsafe: %is margin elapsed %.2fmAh remain",margin, capacity - consumed)) end -- idle function return idle, 10000 end -- this is an alternate update function that is simply used to track how long it will take to get home -- it's really only used for debugging how the prediction rules are working function track_return_time() if not vehicle:get_likely_flying() then -- no longer flying, idle function return idle, 10000 end local home = ahrs:get_home() local position = ahrs:get_position() if home and position then local now = millis() local home_dist = position:get_distance(home) if home_dist < home_reached_rad then -- calculate the extra time to fly the reached rad distance local time_home = time_to_home() local total_time = time_home + ((now-return_start)/1000) -- display the remaining battery capacity on the triggered monitor local capacity = battery:pack_capacity_mah(trigger_instance) local consumed = battery:consumed_mah(trigger_instance) if capacity and consumed then -- estimate the extra capacity used for the reached rad distance return_capacity = return_amps * time_home * (1000 / 60^2) -- convert from amp second's to mAh gcs:send_text(0, "Failsafe: RTL took " .. tostring(total_time) .. string.format("s, %.2fmAh remain", capacity - consumed - return_capacity) ) if margin > 0 then return margin_update, margin*1000 end else gcs:send_text(0, "Failsafe: RTL took " .. tostring(total_time) .. " s") end -- idle function return idle, 10000 end -- print updates tracking progress if last_print + (print_time * 1000) < now and print_time > 0 then last_print = now local return_time = time_to_home() if (return_time < 0) then gcs:send_text(6, "Failsafe: ground speed low can not get home") elseif (return_time > 0) then local total_time = return_time + ((now-return_start)/1000) -- cannot get string.format() to work with total time, wrong variable type? ie not %f or %i? gcs:send_text(0, "Failsafe: Estimated " .. tostring(total_time) .. string.format("s, %.0fs remain", return_time) ) end end end return track_return_time, 100 end -- the main update function that is used to decide when we should do a failsafe function update() local now = millis(); -- check armed if not arming:is_armed() then --gcs:send_text(0, "Failsafe: disabled: not armed") timer_start_time = now timer_active = true return update, 100 end -- check flying if not vehicle:get_likely_flying() then --gcs:send_text(0, "Failsafe: disabled: not flying") timer_start_time = now timer_active = true return update, 100 end -- check mode local current_mode = vehicle:get_mode() if current_mode >= 17 then --gcs:send_text(0, "Failsafe: disabled: Q mode") timer_start_time = now timer_active = true return update, 100 end -- check altitude if alt_min ~= 0 then local dist = ahrs:get_relative_position_NED_home() if not dist or -1*dist:z() < alt_min then --gcs:send_text(0, "Failsafe: disabled: low alt") timer_start_time = now timer_active = true return update, 100 end end -- check timer if now - timer_start_time < (min_flying_time * 1000) then --gcs:send_text(0, "Failsafe: disabled: timer") return update, 100 end -- notify that we have started if timer_active then gcs:send_text(0, "Smart Battery RTL started monitoring") timer_active = false end -- check airspeed local air_speed_in = ahrs:airspeed_estimate() if not air_speed_in then error("Could not read airspeed") end if air_speed_in < min_air_speed * 0.75 then -- we are not flying fast enough, skip but don't reset the timer return update, 100 end local min_remaining_time = 86400 -- 24 hours -- find the return time and airspeed local return_time, return_airspeed = time_to_home() -- default to no normalization local q = 1 local return_q = 1 -- normalize current with dynamic pressure if airspeed_normalize then -- we could probably just use air speed^2 local press = baro:get_pressure() local temp = baro:get_external_temperature() + 273.2 -- convert deg centigrade to kelvin local density = press / (temp * 287.058) -- calculate the air density, ideal gas law, constant is (R) specific gas constant for air q = 0.5 * density * air_speed_in^2 return_q = 0.5 * density * return_airspeed^2 -- we could estimate the change in density also, but will be negligible end for i = 1, #batt_info do local instance, norm_filtered_amps, rated_capacity_mah = table.unpack(batt_info[i]) local amps = battery:current_amps(instance) local consumed_mah = battery:consumed_mah(instance) if amps and consumed_mah then local norm_amps = amps / q -- update all the current consumption rates norm_filtered_amps = (norm_filtered_amps * filter) + (norm_amps * (1.0 - filter)) batt_info[i][2] = norm_filtered_amps -- calculate the estimated return amps, estimate the return current if we were to fly at a different airspeed return_amps = norm_filtered_amps * return_q local remaining_capacity = (rated_capacity_mah - consumed_mah) * 3.6 -- amp seconds (60^2 / 1000) local remaining_time = remaining_capacity / return_amps local buffer_time = remaining_time - ((return_time * time_SF) + margin) if (return_time < 0) or buffer_time < 0 then if return_time < 0 then gcs:send_text(0, "Failsafe: ground speed low can not get home") elseif #batt_info == 1 then gcs:send_text(0, string.format("Failsafe: Estimated %.0fs to home", return_time)) else trigger_instance = instance gcs:send_text(0, string.format("Failsafe: Estimated %.0fs to home, instance %i", return_time, instance)) end last_print = now -- FIXME: We need more insight into what the vehicles already doing. IE don't trigger RTL if we are already landing vehicle:set_mode(11) -- plane RTL FIXME: we need a set of enums defined for the vehicles -- swap to tracking the time rather then re trigger return_start = now -- Print the return distance --[[local home = ahrs:get_home() local position = ahrs:get_position() if home and position then return_distance = position:get_distance(home) end gcs:send_text(0, string.format("Failsafe: %.0f m to home", return_distance))]] -- print the current draw we estimate --gcs:send_text(0, string.format("Failsafe: %.2fa", return_amps)) return track_return_time, 100 end min_remaining_time = math.min(min_remaining_time, buffer_time) end end -- print updates tracking progress if last_print + (print_time * 1000) < now and print_time > 0 then last_print = now gcs:send_text(6, string.format("%.0f seconds of flight remaining before RTL", min_remaining_time)) end return update, 100 end -- validate that all the expected monitors have current monitoring capability, and fetch initial values for i = 1, #batt_info do -- check that the instance exists local instance = batt_info[i][1] if instance > battery:num_instances() then error("Battery " .. instance .. " does not exist") end -- check that we can actually read current from the instance if not battery:current_amps(instance) then error("Battery " .. instance .. " does not support current monitoring") end -- store the pack capacity for later use, it's assumed to never change mid flight -- subtract the capacity we want remaining when we get home local rated_cap = battery:pack_capacity_mah(instance) if rated_cap then -- read in the critical MAH local param_string = 'BATT' .. tostring(instance + 1) .. '_CRT_MAH' if instance == 0 then param_string = 'BATT_CRT_MAH' end local value = param:get(param_string) if not value then error('LUA: get '.. param_string .. ' failed') end batt_info[i][3] = rated_cap - (batt_info[i][4] + value) else error("Battery " .. instance .. " does not support current monitoring") end end return update, 100