--[[ perform simple aerobatic manoeuvres in AUTO mode
cmd = 1: axial rolls, arg1 = roll rate dps, arg2 = number of rolls
cmd = 2: loops or 180deg return, arg1 = pitch rate dps, arg2 = number of loops, if zero do a 1/2 cuban8-like return
cmd = 3: rolling circle, arg1 = earth frame yaw rate, dps, arg2 = roll rate, dps
cmd = 4: knife edge at any angle, arg1 = roll angle to hold, arg2 = duration
cmd = 5: pause, holding heading and alt to allow stabilization after a move, arg1 = duration in seconds
]]--
-- setup param block for aerobatics, reserving 30 params beginning with AERO_
local PARAM_TABLE_KEY = 70
assert(param:add_table(PARAM_TABLE_KEY, "AEROM_", 30), 'could not add param table')
-- this control script uses AERO_TRICK_ID to report the selected trick number from the scripting_rc_selection rc channel
assert(param:add_param(PARAM_TABLE_KEY, 1, 'HGT_P', 1), 'could not add param4') -- height P gain
assert(param:add_param(PARAM_TABLE_KEY, 2, 'HGT_I', 2), 'could not add param5') -- height I gain
assert(param:add_param(PARAM_TABLE_KEY, 3, 'HGT_KE_ADD', 20), 'could not add param6') --height knife-edge addition for pitch
assert(param:add_param(PARAM_TABLE_KEY, 4, 'THR_PIT_FF', 80), 'could not add param67') --throttle FF from pitch
assert(param:add_param(PARAM_TABLE_KEY, 5, 'SPD_P', 5), 'could not add param8') -- speed P gain
assert(param:add_param(PARAM_TABLE_KEY, 6, 'SPD_I', 25), 'could not add param9') -- speed I gain
DO_JUMP = 177
k_throttle = 70
local HGT_P = Parameter("AEROM_HGT_P") -- height P gain
local HGT_I = Parameter("AEROM_HGT_I") -- height I gain
local HGT_KE_BIAS = Parameter("AEROM_HGT_KE_ADD") -- height knifeedge addition for pitch
local THR_PIT_FF = Parameter("AEROM_THR_PIT_FF") -- throttle FF from pitch
local SPD_P = Parameter("AEROM_SPD_P") -- speed P gain
local SPD_I = Parameter("AEROM_SPD_I") -- speed I gain
local TRIM_THROTTLE = Parameter("TRIM_THROTTLE")
local TRIM_ARSPD_CM = Parameter("TRIM_ARSPD_CM")
local RLL2SRV_TCONST = Parameter("RLL2SRV_TCONST")
local PITCH_TCONST = Parameter("PTCH2SRV_TCONST")
local last_roll_err = 0.0
local last_id = 0
local initial_yaw_deg = 0
local wp_yaw_deg = 0
local initial_height = 0
local repeat_count = 0
local running = false
local roll_stage = 0
-- constrain a value between limits
function constrain(v, vmin, vmax)
if v < vmin then
v = vmin
end
if v > vmax then
v = vmax
end
return v
end
-- roll angle error 180 wrap to cope with errors while in inverted segments
function roll_angle_error_wrap(roll_angle_error)
if math.abs(roll_angle_error) > 180 then
if roll_angle_error > 0 then
roll_angle_error = roll_angle_error - 360
else
roll_angle_error= roll_angle_error +360
end
end
return roll_angle_error
end
--roll controller to keep wings level in earth frame. if arg is 0 then level is at only 0 deg, otherwise its at 180/-180 roll also for loops
function earth_frame_wings_level(arg)
local roll_deg = math.deg(ahrs:get_roll())
local roll_angle_error = 0.0
if (roll_deg > 90 or roll_deg < -90) and arg ~= 0 then
roll_angle_error = 180 - roll_deg
else
roll_angle_error = - roll_deg
end
return roll_angle_error_wrap(roll_angle_error)/(RLL2SRV_TCONST:get())
end
function wrap_360(angle)
local res = math.fmod(angle, 360.0)
if res < 0 then
res = res + 360.0
end
return res
end
function wrap_180(angle)
local res = wrap_360(angle)
if res > 180 then
res = res - 360
end
return res
end
-- a PI controller implemented as a Lua object
local function PI_controller(kP,kI,iMax)
-- the new instance. You can put public variables inside this self
-- declaration if you want to
local self = {}
-- private fields as locals
local _kP = kP or 0.0
local _kI = kI or 0.0
local _kD = kD or 0.0
local _iMax = iMax
local _last_t = nil
local _I = 0
local _P = 0
local _total = 0
local _counter = 0
local _target = 0
local _current = 0
-- update the controller.
function self.update(target, current)
local now = millis():tofloat() * 0.001
if not _last_t then
_last_t = now
end
local dt = now - _last_t
_last_t = now
local err = target - current
_counter = _counter + 1
local P = _kP * err
_I = _I + _kI * err * dt
if _iMax then
_I = constrain(_I, -_iMax, iMax)
end
local I = _I
local ret = P + I
_target = target
_current = current
_P = P
_total = ret
return ret
end
-- reset integrator to an initial value
function self.reset(integrator)
_I = integrator
end
function self.set_I(I)
_kI = I
end
function self.set_P(P)
_kP = P
end
function self.set_Imax(Imax)
_iMax = Imax
end
-- log the controller internals
function self.log(name, add_total)
-- allow for an external addition to total
logger:write(name,'Targ,Curr,P,I,Total,Add','ffffff',_target,_current,_P,_I,_total,add_total)
end
-- return the instance
return self
end
local function height_controller(kP_param,kI_param,KnifeEdge_param,Imax)
local self = {}
local kP = kP_param
local kI = kI_param
local KnifeEdge = KnifeEdge_param
local PI = PI_controller(kP:get(), kI:get(), Imax)
function self.update(target)
local target_pitch = PI.update(target, ahrs:get_position():alt()*0.01)
local roll_rad = ahrs:get_roll()
local ke_add = math.abs(math.sin(roll_rad)) * KnifeEdge:get()
target_pitch = target_pitch + ke_add
PI.log("HPI", ke_add)
return target_pitch
end
function self.reset()
PI.reset(math.max(math.deg(ahrs:get_pitch()), 3.0))
PI.set_P(kP:get())
PI.set_I(kI:get())
end
return self
end
local height_PI = height_controller(HGT_P, HGT_I, HGT_KE_BIAS, 20.0)
local speed_PI = PI_controller(SPD_P:get(), SPD_I:get(), 100.0)
-- a controller to target a zero pitch angle and zero heading change, used in a roll
-- output is a body frame pitch rate, with convergence over time tconst in seconds
function pitch_controller(target_pitch_deg, target_yaw_deg, tconst)
local roll_deg = math.deg(ahrs:get_roll())
local pitch_deg = math.deg(ahrs:get_pitch())
local yaw_deg = math.deg(ahrs:get_yaw())
-- get earth frame pitch and yaw rates
local ef_pitch_rate = (target_pitch_deg - pitch_deg) / tconst
local ef_yaw_rate = wrap_180(target_yaw_deg - yaw_deg) / tconst
local bf_pitch_rate = math.sin(math.rad(roll_deg)) * ef_yaw_rate + math.cos(math.rad(roll_deg)) * ef_pitch_rate
local bf_yaw_rate = math.cos(math.rad(roll_deg)) * ef_yaw_rate - math.sin(math.rad(roll_deg)) * ef_pitch_rate
return bf_pitch_rate, bf_yaw_rate
end
-- a controller for throttle to account for pitch
function throttle_controller()
local pitch_rad = ahrs:get_pitch()
local thr_ff = THR_PIT_FF:get()
local throttle = TRIM_THROTTLE:get() + math.sin(pitch_rad) * thr_ff
return constrain(throttle, 0, 100.0)
end
-- recover entry altitude
function recover_alt()
local target_pitch = height_PI.update(initial_height)
local pitch_rate, yaw_rate = pitch_controller(target_pitch, wp_yaw_deg, PITCH_TCONST:get())
return target_pitch, pitch_rate, yaw_rate
end
-- start of trick routines---------------------------------------------------------------------------------
function do_axial_roll(arg1, arg2)
-- constant roll rate axial roll, arg1 roll rate, arg2 is number of rolls
if not running then
running = true
repeat_count = arg2 -1
roll_stage = 0
height_PI.reset()
gcs:send_text(0, string.format("Starting roll"))
end
local roll_rate = arg1
local pitch_deg = math.deg(ahrs:get_pitch())
local roll_deg = math.deg(ahrs:get_roll())
if roll_stage == 0 then
if roll_deg > 45 then
roll_stage = 1
end
elseif roll_stage == 1 then
if roll_deg > -5 and roll_deg < 5 then
-- we're done with a roll
gcs:send_text(0, string.format("Finished roll r=%.1f p=%.1f", roll_deg, pitch_deg))
if repeat_count > 0 then
roll_stage = 0
repeat_count = repeat_count - 1
else
running = false
vehicle:nav_script_time_done(last_id)
roll_stage = 2
return
end
end
end
if roll_stage < 2 then
throttle = throttle_controller()
target_pitch = height_PI.update(initial_height)
pitch_rate, yaw_rate = pitch_controller(target_pitch, wp_yaw_deg, PITCH_TCONST:get())
vehicle:set_target_throttle_rate_rpy(throttle, roll_rate, pitch_rate, yaw_rate)
end
end
local loop_stage = 0
local target_vel
function do_loop(arg1, arg2)
-- do one loop with controllable pitch rate arg1 is pitch rate, arg2 number of loops, 0 indicates 1/2 cuban8 reversal
if not running then
running = true
loop_stage = 0
repeat_count = arg2 -1
target_vel = ahrs:get_velocity_NED():length()
if arg2 ~=0 then
gcs:send_text(0, string.format("Starting loop"))
else
gcs:send_text(0, string.format("Starting immelman"))
end
end
local throttle = throttle_controller()
local pitch_deg = math.deg(ahrs:get_pitch())
local roll_deg = math.deg(ahrs:get_roll())
local vel = ahrs:get_velocity_NED():length()
local pitch_rate = arg1
local pitch_rate = pitch_rate * (1+ 2*((vel/target_vel)-1)) --increase/decrease rate based on velocity to round loop
pitch_rate = constrain(pitch_rate,.5 * arg1, 3 * arg1)
if loop_stage == 0 then
if pitch_deg > 60 then
loop_stage = 1
end
elseif loop_stage == 1 then
if (math.abs(roll_deg) < 90 and pitch_deg > -5 and pitch_deg < 5 and repeat_count >= 0) then
-- we're done with loop
gcs:send_text(0, string.format("Finished loop p=%.1f", pitch_deg))
loop_stage = 2 --now recover stage
height_PI.reset()
elseif (math.abs(roll_deg) > 90 and pitch_deg > -5 and pitch_deg < 5 and repeat_count < 0) then
gcs:send_text(0, string.format("Finished immelman p=%.1f", pitch_deg))
loop_stage = 2 --now recover stage
height_PI.reset()
end
elseif loop_stage == 2 then
-- recover alt if above or below start and terminate
if math.abs(ahrs:get_position():alt()*0.01 - initial_height) > 3 then
throttle, pitch_rate, yaw_rate = recover_alt()
elseif repeat_count > 0 then
loop_stage = 0
repeat_count = repeat_count - 1
else
running = false
--gcs:send_text(0, string.format("Recovered entry alt"))
vehicle:nav_script_time_done(last_id)
return
end
end
throttle = throttle_controller()
if loop_stage == 2 or loop_stage == 0 then
level_type = 0
else
level_type = 1
end
if math.abs(pitch_deg) > 85 and math.abs(pitch_deg) < 95 then
roll_rate = 0
else
roll_rate = earth_frame_wings_level(level_type)
end
vehicle:set_target_throttle_rate_rpy(throttle, roll_rate, pitch_rate, 0)
end
local rolling_circle_stage = 0
local rolling_circle_yaw = 0
local rolling_circle_last_ms = 0
function do_rolling_circle(arg1, arg2)
-- constant roll rate circle roll, arg1 = earth frame yaw rate, dps, positive to right, neg to left, arg2 = roll rate, dps
if not running then
running = true
rolling_circle_stage = 0
rolling_circle_yaw_deg = 0
rolling_circle_last_ms = millis()
height_PI.reset()
gcs:send_text(0, string.format("Starting rolling circle"))
end
local yaw_rate_dps = arg1
local roll_rate_dps = arg2
local pitch_deg = math.deg(ahrs:get_pitch())
local roll_deg = math.deg(ahrs:get_roll())
local yaw_deg = math.deg(ahrs:get_yaw())
local now_ms = millis()
local dt = (now_ms - rolling_circle_last_ms):tofloat() * 0.001
rolling_circle_last_ms = now_ms
rolling_circle_yaw_deg = rolling_circle_yaw_deg + yaw_rate_dps * dt
if rolling_circle_stage == 0 then
if math.abs(rolling_circle_yaw_deg) > 10.0 then
rolling_circle_stage = 1
end
elseif rolling_circle_stage == 1 then
if math.abs(rolling_circle_yaw_deg) >= 360.0 then
running = false
-- we're done
gcs:send_text(0, string.format("Finished rollcircle r=%.1f p=%.1f", roll_deg, pitch_deg))
vehicle:nav_script_time_done(last_id)
rolling_circle_stage = 2
return
end
end
if rolling_circle_stage < 2 then
target_pitch = height_PI.update(initial_height)
vel = ahrs:get_velocity_NED()
pitch_rate, yaw_rate = pitch_controller(target_pitch, wrap_360(rolling_circle_yaw_deg+initial_yaw_deg), PITCH_TCONST:get())
throttle = throttle_controller()
throttle = constrain(throttle, 0, 100.0)
vehicle:set_target_throttle_rate_rpy(throttle, roll_rate_dps, pitch_rate, yaw_rate)
end
end
local knife_edge_ms = 0
function do_knife_edge(arg1,arg2)
-- arg1 is angle +/-180, duration is arg2
local now = millis():tofloat() * 0.001
if not running then
running = true
height_PI.reset()
knife_edge_s = now
gcs:send_text(0, string.format("%d Knife edge", arg1))
end
local i=0
if (now - knife_edge_s) < arg2 then
local roll_deg = math.deg(ahrs:get_roll())
local roll_angle_error = (arg1 - roll_deg)
if math.abs(roll_angle_error) > 180 then
if roll_angle_error > 0 then
roll_angle_error = roll_angle_error - 360
else
roll_angle_error= roll_angle_error +360
end
end
roll_rate = roll_angle_error/RLL2SRV_TCONST:get()
target_pitch = height_PI.update(initial_height)
pitch_rate, yaw_rate = pitch_controller(target_pitch, wp_yaw_deg, PITCH_TCONST:get())
throttle = throttle_controller()
vehicle:set_target_throttle_rate_rpy(throttle, roll_rate, pitch_rate, yaw_rate)
else
gcs:send_text(0, string.format("Finished Knife edge", arg1))
vehicle:nav_script_time_done(last_id)
return
end
end
-- fly level for a time..allows full altitude recovery after trick
function do_pause(arg1,arg2)
-- arg1 is time of pause in sec, arg2 is unused
local now = millis():tofloat() * 0.001
if not running then
running = true
height_PI.reset()
knife_edge_s = now
gcs:send_text(0, string.format("%dsec Pause", arg1))
end
local i=0
if (now - knife_edge_s) < arg1 then
roll_rate = earth_frame_wings_level(0)
target_pitch = height_PI.update(initial_height)
pitch_rate, yaw_rate = pitch_controller(target_pitch, wp_yaw_deg, PITCH_TCONST:get())
throttle = throttle_controller()
vehicle:set_target_throttle_rate_rpy(throttle, roll_rate, pitch_rate, yaw_rate)
else
vehicle:nav_script_time_done(last_id)
return
end
end
function get_wp_location(i)
local m = mission:get_item(i)
local loc = Location()
loc:lat(m:x())
loc:lng(m:y())
loc:relative_alt(false)
loc:terrain_alt(false)
loc:origin_alt(false)
loc:alt(math.floor(m:z()*100))
return loc
end
function resolve_jump(i)
local m = mission:get_item(i)
while m:command() == DO_JUMP do
i = math.floor(m:param1())
m = mission:get_item(i)
end
return i
end
function update()
id, cmd, arg1, arg2, arg3, arg4 = vehicle:nav_script_time()
if id then
if id ~= last_id then
-- we've started a new command
running = false
last_id = id
repeat_count = 0
initial_yaw_deg = math.deg(ahrs:get_yaw())
initial_height = ahrs:get_position():alt()*0.01
-- work out yaw between previous WP and next WP
local cnum = mission:get_current_nav_index()
-- find previous nav waypoint
local loc_prev = get_wp_location(cnum-1)
local loc_next = get_wp_location(cnum+1)
local i= cnum-1
while get_wp_location(i):lat() == 0 and get_wp_location(i):lng() == 0 do
i = i-1
loc_prev = get_wp_location(i)
end
-- find next nav waypoint
i = cnum+1
while get_wp_location(i):lat() == 0 and get_wp_location(i):lng() == 0 do
i = i+1
loc_next = get_wp_location(resolve_jump(i))
end
wp_yaw_deg = math.deg(loc_prev:get_bearing(loc_next))
end
if cmd == 1 then
do_axial_roll(arg1, arg2)
elseif cmd == 2 then
do_loop(arg1, arg2)
elseif cmd == 3 then
do_rolling_circle(arg1, arg2)
elseif cmd ==4 then
do_knife_edge(arg1,arg2)
elseif cmd == 5 then
do_pause(arg1,arg2)
end
else
running = false
end
return update, 10
end
return update()