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nexedi
flight-scripts
Commits
8d1d1ecb
Commit
8d1d1ecb
authored
Jun 16, 2023
by
Léo-Paul Géneau
👾
Browse files
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Add swarm flight scripts
parent
c55e7090
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4 changed files
with
1317 additions
and
0 deletions
+1317
-0
collision_avoidance.js
collision_avoidance.js
+352
-0
fixed_wings_swarm.js
fixed_wings_swarm.js
+370
-0
gnss_denial.js
gnss_denial.js
+349
-0
v.js
v.js
+246
-0
No files found.
collision_avoidance.js
0 → 100644
View file @
8d1d1ecb
/*
* The point of this scenario is to prove that failsafes can be coded. It is
* supposed to be tested with only 2 drones.
* The leader follows a path of checkpoints. The follower tries to follow it at
* a distance of TARGETED_DISTANCE (30) meters. When the distance between the 2
* UAVs is lesser than SAFETY_DISTANCE (50) meters, the follower increases its
* regular flight altitude (535 meters) by OVERRIDE_ALTITUDE (20) meters.
*/
/*jslint nomen: true, indent: 2, maxerr: 3, maxlen: 80 */
/*global console, me*/
(
function
(
console
,
me
)
{
"
use strict
"
;
var
ALTITUDE_DIFF
=
20
,
BASE_ALTITUDE
=
515
,
CHECKPOINT_LIST
=
[
{
latitude
:
45.56328
,
longitude
:
13.90470
},
{
latitude
:
45.55926
,
longitude
:
13.90522
},
{
latitude
:
45.55087
,
longitude
:
13.91845
},
{
latitude
:
45.55487
,
longitude
:
13.91807
}
],
EPSILON_ALTITUDE
=
1
,
LOITER_RADIUS
=
100
,
LOITER_ACCEPTANCE
=
105
,
OVERRIDE_ALTITUDE
=
20
,
PARACHUTE_ALTITUDE
=
473
,
PARACHUTE_EPSILON
=
10
,
PARACHUTE_POINT
=
{
altitude
:
463
,
latitude
:
45.55808
,
longitude
:
13.91086
},
PARACHUTE_YAW
=
-
42
,
R
=
6371
e3
,
RALLY_POINT
=
{
altitude
:
435
,
latitude
:
45.55601
,
longitude
:
13.91483
},
REGULAR_EPSILON
=
50
,
SAFETY_DISTANCE
=
50
,
START_DISTANCE
=
200
,
TARGETED_DISTANCE
=
30
,
TAKE_OFF_POINT
=
{
latitude
:
45.55938
,
longitude
:
13.90846
},
TIMESTAMP_ACCEPTANCE
=
1000
,
YAW_EPSILON
=
5
,
MIN_SPEED
=
17
,
DEFAULT_SPEED
=
18
,
MAX_SPEED
=
20
,
SPEED_FACTOR
=
0.2
;
function
exitOnFail
(
ret
,
msg
)
{
if
(
ret
)
{
console
.
log
(
msg
);
me
.
exit
(
1
);
}
}
function
deployParachute
(
drone
)
{
console
.
log
(
"
Deploying parachute
"
);
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
false
,
state
:
"
Landed
"
,
type
:
"
state
"
}
));
exitOnFail
(
drone
.
triggerParachute
(),
"
Failed to deploy parachute
"
);
me
.
exit
(
0
);
}
function
toRad
(
angle
)
{
return
Math
.
PI
*
angle
/
180
;
}
function
distance
(
lat1
,
lon1
,
lat2
,
lon2
)
{
var
la1
=
toRad
(
lat1
),
la2
=
toRad
(
lat2
),
lo1
=
toRad
(
lon1
),
lo2
=
toRad
(
lon2
),
haversine_phi
=
Math
.
pow
(
Math
.
sin
((
la2
-
la1
)
/
2
),
2
),
sin_lon
=
Math
.
sin
((
lo2
-
lo1
)
/
2
),
h
=
haversine_phi
+
Math
.
cos
(
la1
)
*
Math
.
cos
(
la2
)
*
sin_lon
*
sin_lon
;
return
2
*
R
*
Math
.
asin
(
Math
.
sqrt
(
h
));
}
function
leaderId
(
drone
)
{
return
drone
.
id_list
[
0
];
}
function
pointReached
(
drone
,
point
,
acceptance
)
{
var
current_position
=
drone
.
getCurrentPosition
(),
dist
=
distance
(
current_position
.
x
,
current_position
.
y
,
point
.
latitude
,
point
.
longitude
);
console
.
log
(
"
Distance to point
"
,
dist
);
return
dist
<=
acceptance
;
}
me
.
onStart
=
function
()
{
me
.
direction_set
=
false
;
me
.
flightAltitude
=
BASE_ALTITUDE
+
me
.
id
*
ALTITUDE_DIFF
;
me
.
following
=
false
;
me
.
going_to_rally
=
false
;
me
.
id_list
=
Object
.
keys
(
me
.
drone_dict
).
map
((
x
)
=>
Number
(
x
));
me
.
id_list
.
sort
();
me
.
landing
=
false
;
me
.
next_checkpoint
=
0
;
me
.
parachute_altitude_reached
=
false
;
me
.
parachute_yaw_reached
=
false
;
me
.
started
=
false
;
me
.
setAirSpeed
(
DEFAULT_SPEED
);
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Ready
"
,
type
:
"
state
"
}
));
};
me
.
onUpdate
=
function
(
timestamp
)
{
var
checkpointIndex
,
distance2d
,
distanceDiff
,
distanceToTakeOffPoint
,
leader_id
=
leaderId
(
me
),
me_index
=
me
.
id_list
.
indexOf
(
me
.
id
),
neighbor_id
=
me
.
id_list
[(
!
me
.
reverse
)
?
me_index
-
1
:
me_index
+
1
],
newSpeed
,
position
=
me
.
getCurrentPosition
();
if
(
!
me
.
started
)
{
if
(
leader_id
!==
me
.
id
)
{
console
.
log
(
"
timestamp difference
"
,
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
);
}
return
;
}
if
(
!
me
.
landing
)
{
if
(
leader_id
!==
me
.
id
)
{
distance2d
=
distance
(
position
.
x
,
position
.
y
,
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
);
if
(
!
me
.
following
)
{
distanceToTakeOffPoint
=
distance
(
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
,
TAKE_OFF_POINT
.
latitude
,
TAKE_OFF_POINT
.
longitude
);
console
.
log
(
"
Distance from neighbor to takeoff point
"
,
distanceToTakeOffPoint
);
if
(
distanceToTakeOffPoint
<
START_DISTANCE
)
{
return
;
}
me
.
following
=
true
;
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Flying
"
,
type
:
"
state
"
}
));
}
if
(
Math
.
abs
(
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
)
>=
TIMESTAMP_ACCEPTANCE
)
{
console
.
log
(
"
timestamp difference
"
,
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
);
return
;
}
distanceDiff
=
distance2d
-
TARGETED_DISTANCE
;
newSpeed
=
Math
.
max
(
Math
.
min
(
distanceDiff
*
SPEED_FACTOR
+
DEFAULT_SPEED
,
MAX_SPEED
),
MIN_SPEED
);
me
.
setAirSpeed
(
newSpeed
);
if
(
distance2d
<
SAFETY_DISTANCE
)
{
me
.
flightAltitude
=
BASE_ALTITUDE
+
me
.
id
*
ALTITUDE_DIFF
+
OVERRIDE_ALTITUDE
;
}
else
{
me
.
flightAltitude
=
BASE_ALTITUDE
+
me
.
id
*
ALTITUDE_DIFF
;
}
me
.
setTargetCoordinates
(
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
,
me
.
flightAltitude
);
console
.
log
(
"
distance to leader
"
,
distance
(
position
.
x
,
position
.
y
,
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
)
);
return
;
}
checkpointIndex
=
(
!
me
.
reverse
)
?
me
.
next_checkpoint
:
CHECKPOINT_LIST
.
length
-
me
.
next_checkpoint
-
1
;
if
(
!
me
.
direction_set
)
{
console
.
log
(
"
Going to Checkpoint
"
,
checkpointIndex
);
me
.
setTargetCoordinates
(
CHECKPOINT_LIST
[
checkpointIndex
].
latitude
,
CHECKPOINT_LIST
[
checkpointIndex
].
longitude
,
me
.
flightAltitude
);
me
.
direction_set
=
true
;
}
if
(
pointReached
(
me
,
CHECKPOINT_LIST
[
checkpointIndex
],
REGULAR_EPSILON
)
)
{
console
.
log
(
"
Reached Checkpoint
"
,
checkpointIndex
);
me
.
next_checkpoint
+=
1
;
me
.
next_checkpoint
%=
CHECKPOINT_LIST
.
length
;
me
.
direction_set
=
false
;
me
.
sendMsg
(
JSON
.
stringify
({
type
:
"
checkpoint
"
,
next_checkpoint
:
me
.
next_checkpoint
}));
}
return
;
}
if
(
me
.
going_to_rally
)
{
if
(
pointReached
(
me
,
RALLY_POINT
,
LOITER_ACCEPTANCE
))
{
console
.
log
(
"
Arrived to rally
"
);
me
.
going_to_rally
=
false
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
PARACHUTE_ALTITUDE
,
LOITER_RADIUS
);
}
return
;
}
if
(
!
me
.
parachute_altitude_reached
)
{
console
.
log
(
"
Altitude
"
,
me
.
getAltitudeAbs
());
if
(
Math
.
abs
(
me
.
getAltitudeAbs
()
-
PARACHUTE_ALTITUDE
)
<=
EPSILON_ALTITUDE
)
{
me
.
parachute_altitude_reached
=
true
;
}
return
;
}
if
(
!
me
.
parachute_yaw_reached
)
{
console
.
log
(
"
Yaw:
"
,
me
.
getYaw
());
if
(
Math
.
abs
(
me
.
getYaw
()
-
PARACHUTE_YAW
)
<=
YAW_EPSILON
)
{
me
.
parachute_yaw_reached
=
true
;
me
.
setTargetCoordinates
(
PARACHUTE_POINT
.
latitude
,
PARACHUTE_POINT
.
longitude
,
PARACHUTE_POINT
.
altitude
);
}
return
;
}
if
(
pointReached
(
me
,
PARACHUTE_POINT
,
PARACHUTE_EPSILON
))
{
deployParachute
(
me
);
}
};
me
.
onGetMsg
=
function
(
msg
)
{
var
msgDict
=
JSON
.
parse
(
msg
);
if
(
msgDict
.
hasOwnProperty
(
"
status
"
))
{
switch
(
msgDict
.
status
)
{
case
"
running
"
:
me
.
started
=
true
;
if
(
me
.
id
===
leaderId
(
me
))
{
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Flying
"
,
type
:
"
state
"
}
));
}
break
;
case
"
stopped
"
:
if
(
me
.
id
===
me
.
id_list
[
0
])
{
me
.
landing
=
true
;
me
.
going_to_rally
=
true
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
me
.
flightAltitude
,
LOITER_RADIUS
);
}
break
;
default
:
console
.
log
(
"
Unknown status:
"
,
me
.
msgDict
.
status
);
}
return
;
}
switch
(
msgDict
.
type
)
{
case
"
state
"
:
if
(
msgDict
.
state
===
"
Landed
"
)
{
me
.
id_list
.
splice
(
me
.
id_list
.
indexOf
(
msgDict
.
id
),
1
);
if
(
me
.
id
===
me
.
id_list
[
0
])
{
me
.
landing
=
true
;
me
.
going_to_rally
=
true
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
me
.
flightAltitude
,
LOITER_RADIUS
);
}
}
break
;
default
:
console
.
log
(
"
Unknown message type:
"
+
msgDict
.
type
);
}
};
}(
console
,
me
));
fixed_wings_swarm.js
0 → 100644
View file @
8d1d1ecb
/*
* In this flight the leader follows continuously a list of checkpoints when a
* start signal is send. The other drones follow each other (second drone
* follows leader, third drone follows second drone, ...). When the switch
* signal is sent, the last drone becomes the leader and follow the checkpoints
* in the reversed order. When stop signal is sent, each drone lands one at the
* time from the last one to the leader.
*/
/*jslint nomen: true, indent: 2, maxerr: 3, maxlen: 80 */
/*global console, me*/
(
function
(
console
,
me
)
{
"
use strict
"
;
var
ALTITUDE_DIFF
=
10
,
BASE_ALTITUDE
=
505
,
CHECKPOINT_LIST
=
[
{
latitude
:
45.56328
,
longitude
:
13.90470
},
{
latitude
:
45.55926
,
longitude
:
13.90522
},
{
latitude
:
45.55087
,
longitude
:
13.91845
},
{
latitude
:
45.55487
,
longitude
:
13.91807
}
],
EPSILON_ALTITUDE
=
1
,
LOITER_RADIUS
=
100
,
LOITER_ACCEPTANCE
=
105
,
PARACHUTE_ALTITUDE
=
473
,
PARACHUTE_EPSILON
=
10
,
PARACHUTE_POINT
=
{
altitude
:
463
,
latitude
:
45.55808
,
longitude
:
13.91086
},
PARACHUTE_YAW
=
-
42
,
R
=
6371
e3
,
RALLY_POINT
=
{
altitude
:
435
,
latitude
:
45.55601
,
longitude
:
13.91483
},
REGULAR_EPSILON
=
50
,
TARGETED_DISTANCE
=
100
,
TAKE_OFF_POINT
=
{
latitude
:
45.55938
,
longitude
:
13.90846
},
TIMESTAMP_ACCEPTANCE
=
1000
,
YAW_EPSILON
=
5
,
MIN_SPEED
=
17
,
DEFAULT_SPEED
=
18
,
MAX_SPEED
=
20
,
SPEED_FACTOR
=
0.2
;
function
exitOnFail
(
ret
,
msg
)
{
if
(
ret
)
{
console
.
log
(
msg
);
me
.
exit
(
1
);
}
}
function
sendLandingMessage
(
drone
)
{
console
.
log
(
"
Landing
"
);
drone
.
sendMsg
(
JSON
.
stringify
(
{
id
:
drone
.
id
,
inAir
:
false
,
state
:
"
Landed
"
,
type
:
"
state
"
}
));
}
function
deployParachute
(
drone
)
{
console
.
log
(
"
Deploying parachute
"
);
sendLandingMessage
(
drone
)
exitOnFail
(
drone
.
triggerParachute
(),
"
Failed to deploy parachute
"
);
}
function
toRad
(
angle
)
{
return
Math
.
PI
*
angle
/
180
;
}
function
distance
(
lat1
,
lon1
,
lat2
,
lon2
)
{
var
la1
=
toRad
(
lat1
),
la2
=
toRad
(
lat2
),
lo1
=
toRad
(
lon1
),
lo2
=
toRad
(
lon2
),
haversine_phi
=
Math
.
pow
(
Math
.
sin
((
la2
-
la1
)
/
2
),
2
),
sin_lon
=
Math
.
sin
((
lo2
-
lo1
)
/
2
),
h
=
haversine_phi
+
Math
.
cos
(
la1
)
*
Math
.
cos
(
la2
)
*
sin_lon
*
sin_lon
;
return
2
*
R
*
Math
.
asin
(
Math
.
sqrt
(
h
));
}
function
leaderId
(
drone
)
{
var
id_list
=
drone
.
id_list
;
return
(
!
drone
.
reverse
)
?
id_list
[
0
]
:
id_list
[
id_list
.
length
-
1
];
}
function
pointReached
(
drone
,
point
,
acceptance
)
{
var
current_position
=
drone
.
getCurrentPosition
(),
dist
=
distance
(
current_position
.
x
,
current_position
.
y
,
point
.
latitude
,
point
.
longitude
);
console
.
log
(
"
Distance to point
"
,
dist
);
return
dist
<=
acceptance
;
}
me
.
onStart
=
function
()
{
me
.
direction_set
=
false
;
me
.
flightAltitude
=
BASE_ALTITUDE
+
me
.
id
*
ALTITUDE_DIFF
;
me
.
following
=
false
;
me
.
going_to_rally
=
false
;
me
.
id_list
=
Object
.
keys
(
me
.
drone_dict
).
map
((
x
)
=>
Number
(
x
));
me
.
id_list
.
sort
();
me
.
landing
=
false
;
me
.
next_checkpoint
=
0
;
me
.
parachute_altitude_reached
=
false
;
me
.
parachute_yaw_reached
=
false
;
me
.
started
=
false
;
me
.
stopped
=
false
;
me
.
reverse
=
false
;
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Ready
"
,
type
:
"
state
"
}
));
};
me
.
onUpdate
=
function
(
timestamp
)
{
var
checkpointIndex
,
distance2d
,
distanceDiff
,
distanceToTakeOffPoint
,
leader_id
=
leaderId
(
me
),
me_index
=
me
.
id_list
.
indexOf
(
me
.
id
),
neighbor_id
=
me
.
id_list
[(
!
me
.
reverse
)
?
me_index
-
1
:
me_index
+
1
],
newSpeed
,
position
=
me
.
getCurrentPosition
();
if
(
me
.
isLanding
())
{
sendLandingMessage
(
me
);
}
if
(
!
me
.
started
)
{
if
(
leader_id
!==
me
.
id
)
{
console
.
log
(
"
timestamp difference
"
,
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
);
}
return
;
}
if
(
!
me
.
landing
)
{
if
(
leader_id
!==
me
.
id
)
{
distance2d
=
distance
(
position
.
x
,
position
.
y
,
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
);
if
(
!
me
.
following
)
{
distanceToTakeOffPoint
=
distance
(
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
,
TAKE_OFF_POINT
.
latitude
,
TAKE_OFF_POINT
.
longitude
);
console
.
log
(
"
Distance from neighbor to takeoff point
"
,
distanceToTakeOffPoint
);
if
(
distanceToTakeOffPoint
<
2
*
TARGETED_DISTANCE
)
{
return
;
}
me
.
following
=
true
;
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Flying
"
,
type
:
"
state
"
}
));
}
if
(
Math
.
abs
(
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
)
>=
TIMESTAMP_ACCEPTANCE
)
{
console
.
log
(
"
timestamp difference
"
,
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
);
return
;
}
me
.
setTargetCoordinates
(
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
,
me
.
flightAltitude
);
distanceDiff
=
distance2d
-
TARGETED_DISTANCE
;
newSpeed
=
Math
.
max
(
Math
.
min
(
distanceDiff
*
SPEED_FACTOR
+
DEFAULT_SPEED
,
MAX_SPEED
),
MIN_SPEED
);
me
.
setAirSpeed
(
newSpeed
);
console
.
log
(
"
distance to leader
"
,
distance
(
position
.
x
,
position
.
y
,
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
)
);
return
;
}
checkpointIndex
=
(
!
me
.
reverse
)
?
me
.
next_checkpoint
:
CHECKPOINT_LIST
.
length
-
me
.
next_checkpoint
-
1
;
if
(
!
me
.
direction_set
)
{
console
.
log
(
"
Going to Checkpoint
"
,
checkpointIndex
);
me
.
setTargetCoordinates
(
CHECKPOINT_LIST
[
checkpointIndex
].
latitude
,
CHECKPOINT_LIST
[
checkpointIndex
].
longitude
,
me
.
flightAltitude
);
me
.
direction_set
=
true
;
}
if
(
pointReached
(
me
,
CHECKPOINT_LIST
[
checkpointIndex
],
REGULAR_EPSILON
)
)
{
console
.
log
(
"
Reached Checkpoint
"
,
checkpointIndex
);
me
.
next_checkpoint
+=
1
;
me
.
next_checkpoint
%=
CHECKPOINT_LIST
.
length
;
me
.
direction_set
=
false
;
me
.
sendMsg
(
JSON
.
stringify
({
type
:
"
checkpoint
"
,
next_checkpoint
:
me
.
next_checkpoint
}));
}
return
;
}
if
(
me
.
going_to_rally
)
{
if
(
pointReached
(
me
,
RALLY_POINT
,
LOITER_ACCEPTANCE
))
{
console
.
log
(
"
Arrived to rally
"
);
me
.
going_to_rally
=
false
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
PARACHUTE_ALTITUDE
,
LOITER_RADIUS
);
}
return
;
}
if
(
!
me
.
parachute_altitude_reached
)
{
console
.
log
(
"
Altitude
"
,
me
.
getAltitudeAbs
());
if
(
Math
.
abs
(
me
.
getAltitudeAbs
()
-
PARACHUTE_ALTITUDE
)
<=
EPSILON_ALTITUDE
)
{
me
.
parachute_altitude_reached
=
true
;
}
return
;
}
if
(
!
me
.
parachute_yaw_reached
)
{
console
.
log
(
"
Yaw:
"
,
me
.
getYaw
());
if
(
Math
.
abs
(
me
.
getYaw
()
-
PARACHUTE_YAW
)
<=
YAW_EPSILON
)
{
me
.
parachute_yaw_reached
=
true
;
me
.
setTargetCoordinates
(
PARACHUTE_POINT
.
latitude
,
PARACHUTE_POINT
.
longitude
,
PARACHUTE_POINT
.
altitude
);
}
return
;
}
if
(
pointReached
(
me
,
PARACHUTE_POINT
,
PARACHUTE_EPSILON
))
{
deployParachute
(
me
);
}
};
me
.
onGetMsg
=
function
(
msg
)
{
var
msgDict
=
JSON
.
parse
(
msg
);
if
(
msgDict
.
hasOwnProperty
(
"
status
"
))
{
switch
(
msgDict
.
status
)
{
case
"
running
"
:
me
.
started
=
true
;
console
.
log
(
"
running
"
);
if
(
me
.
id
===
leaderId
(
me
))
{
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Flying
"
,
type
:
"
state
"
}
));
me
.
setTargetCoordinates
(
CHECKPOINT_LIST
[
me
.
next_checkpoint
].
latitude
,
CHECKPOINT_LIST
[
me
.
next_checkpoint
].
longitude
,
me
.
flightAltitude
);
me
.
direction_set
=
true
;
me
.
setAirSpeed
(
DEFAULT_SPEED
);
}
break
;
case
"
stopped
"
:
me
.
stopped
=
true
;
if
(
me
.
id
===
me
.
id_list
[
0
])
{
me
.
landing
=
true
;
me
.
going_to_rally
=
true
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
me
.
flightAltitude
,
LOITER_RADIUS
);
console
.
log
(
"
Going to rally
"
);
}
break
;
case
"
switch
"
:
me
.
reverse
=
!
me
.
reverse
;
me
.
direction_set
=
false
;
break
;
default
:
console
.
log
(
"
Unknown status:
"
,
me
.
msgDict
.
status
);
}
return
;
}
switch
(
msgDict
.
type
)
{
case
"
checkpoint
"
:
me
.
next_checkpoint
=
msgDict
.
next_checkpoint
;
break
;
case
"
state
"
:
if
(
msgDict
.
state
===
"
Landed
"
&&
me
.
id_list
.
includes
(
msgDict
.
id
))
{
me
.
id_list
.
splice
(
me
.
id_list
.
indexOf
(
msgDict
.
id
),
1
);
if
(
me
.
stopped
&&
me
.
id
===
me
.
id_list
[
0
])
{
me
.
landing
=
true
;
me
.
going_to_rally
=
true
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
me
.
flightAltitude
,
LOITER_RADIUS
);
}
}
break
;
default
:
console
.
log
(
"
Unknown message type:
"
+
msgDict
.
type
);
}
};
}(
console
,
me
));
gnss_denial.js
0 → 100644
View file @
8d1d1ecb
/*
* The point of this scenario is to prove that gps jamming can be detected.
* It is supposed to be tested with only 2 drones.
* The leader follows a path of checkpoints. The follower follows it at
* flying at the altitude of 525 meters. When gps is jammed, the follower
* increases its flight altitude by OVERRIDE_ALTITUDE (20) meters.
*/
/*jslint nomen: true, indent: 2, maxerr: 3, maxlen: 80 */
/*global console, me*/
(
function
(
console
,
me
)
{
"
use strict
"
;
var
ALTITUDE_DIFF
=
20
,
BASE_ALTITUDE
=
515
,
CHECKPOINT_LIST
=
[
{
latitude
:
45.56328
,
longitude
:
13.90470
},
{
latitude
:
45.55926
,
longitude
:
13.90522
},
{
latitude
:
45.55087
,
longitude
:
13.91845
},
{
latitude
:
45.55487
,
longitude
:
13.91807
}
],
EPSILON_ALTITUDE
=
1
,
LOITER_RADIUS
=
100
,
LOITER_ACCEPTANCE
=
105
,
OVERRIDE_ALTITUDE
=
20
,
PARACHUTE_ALTITUDE
=
473
,
PARACHUTE_EPSILON
=
10
,
PARACHUTE_POINT
=
{
altitude
:
463
,
latitude
:
45.55808
,
longitude
:
13.91086
},
PARACHUTE_YAW
=
-
42
,
R
=
6371
e3
,
RALLY_POINT
=
{
altitude
:
435
,
latitude
:
45.55601
,
longitude
:
13.91483
},
REGULAR_EPSILON
=
50
,
TARGETED_DISTANCE
=
100
,
TAKE_OFF_POINT
=
{
latitude
:
45.55938
,
longitude
:
13.90846
},
TIMESTAMP_ACCEPTANCE
=
1000
,
YAW_EPSILON
=
5
,
MIN_SPEED
=
17
,
DEFAULT_SPEED
=
18
,
MAX_SPEED
=
20
,
SPEED_FACTOR
=
0.2
;
function
exitOnFail
(
ret
,
msg
)
{
if
(
ret
)
{
console
.
log
(
msg
);
me
.
exit
(
1
);
}
}
function
deployParachute
(
drone
)
{
console
.
log
(
"
Deploying parachute
"
);
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
false
,
state
:
"
Landed
"
,
type
:
"
state
"
}
));
exitOnFail
(
drone
.
triggerParachute
(),
"
Failed to deploy parachute
"
);
me
.
exit
(
0
);
}
function
toRad
(
angle
)
{
return
Math
.
PI
*
angle
/
180
;
}
function
distance
(
lat1
,
lon1
,
lat2
,
lon2
)
{
var
la1
=
toRad
(
lat1
),
la2
=
toRad
(
lat2
),
lo1
=
toRad
(
lon1
),
lo2
=
toRad
(
lon2
),
haversine_phi
=
Math
.
pow
(
Math
.
sin
((
la2
-
la1
)
/
2
),
2
),
sin_lon
=
Math
.
sin
((
lo2
-
lo1
)
/
2
),
h
=
haversine_phi
+
Math
.
cos
(
la1
)
*
Math
.
cos
(
la2
)
*
sin_lon
*
sin_lon
;
return
2
*
R
*
Math
.
asin
(
Math
.
sqrt
(
h
));
}
function
leaderId
(
drone
)
{
return
drone
.
id_list
[
0
];
}
function
pointReached
(
drone
,
point
,
acceptance
)
{
var
current_position
=
drone
.
getCurrentPosition
(),
dist
=
distance
(
current_position
.
x
,
current_position
.
y
,
point
.
latitude
,
point
.
longitude
);
console
.
log
(
"
Distance to point
"
,
dist
);
return
dist
<=
acceptance
;
}
me
.
onStart
=
function
()
{
me
.
direction_set
=
false
;
me
.
flightAltitude
=
BASE_ALTITUDE
+
me
.
id
*
ALTITUDE_DIFF
;
me
.
following
=
false
;
me
.
going_to_rally
=
false
;
me
.
id_list
=
Object
.
keys
(
me
.
drone_dict
).
map
((
x
)
=>
Number
(
x
));
me
.
id_list
.
sort
();
me
.
landing
=
false
;
me
.
next_checkpoint
=
0
;
me
.
parachute_altitude_reached
=
false
;
me
.
parachute_yaw_reached
=
false
;
me
.
started
=
false
;
me
.
setAirSpeed
(
DEFAULT_SPEED
);
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Ready
"
,
type
:
"
state
"
}
));
};
me
.
onUpdate
=
function
(
timestamp
)
{
var
checkpointIndex
,
distance2d
,
distanceDiff
,
distanceToTakeOffPoint
,
leader_id
=
leaderId
(
me
),
me_index
=
me
.
id_list
.
indexOf
(
me
.
id
),
neighbor_id
=
me
.
id_list
[(
!
me
.
reverse
)
?
me_index
-
1
:
me_index
+
1
],
newSpeed
,
position
=
me
.
getCurrentPosition
();
if
(
!
me
.
started
)
{
if
(
leader_id
!==
me
.
id
)
{
console
.
log
(
"
timestamp difference
"
,
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
);
}
return
;
}
if
(
!
me
.
landing
)
{
if
(
leader_id
!==
me
.
id
)
{
if
(
!
me
.
gpsIsOk
())
{
me
.
flightAltitude
=
BASE_ALTITUDE
+
me
.
id
*
ALTITUDE_DIFF
+
OVERRIDE_ALTITUDE
;
}
else
{
me
.
flightAltitude
=
BASE_ALTITUDE
+
me
.
id
*
ALTITUDE_DIFF
;
}
distance2d
=
distance
(
position
.
x
,
position
.
y
,
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
);
if
(
!
me
.
following
)
{
distanceToTakeOffPoint
=
distance
(
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
,
TAKE_OFF_POINT
.
latitude
,
TAKE_OFF_POINT
.
longitude
);
console
.
log
(
"
Distance from neighbor to takeoff point
"
,
distanceToTakeOffPoint
);
if
(
distanceToTakeOffPoint
<
2
*
TARGETED_DISTANCE
)
{
return
;
}
me
.
following
=
true
;
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Flying
"
,
type
:
"
state
"
}
));
}
if
(
Math
.
abs
(
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
)
>=
TIMESTAMP_ACCEPTANCE
)
{
console
.
log
(
"
timestamp difference
"
,
position
.
timestamp
-
me
.
drone_dict
[
neighbor_id
].
timestamp
);
return
;
}
distanceDiff
=
distance2d
-
TARGETED_DISTANCE
;
newSpeed
=
Math
.
max
(
Math
.
min
(
distanceDiff
*
SPEED_FACTOR
+
DEFAULT_SPEED
,
MAX_SPEED
),
MIN_SPEED
);
me
.
setAirSpeed
(
newSpeed
);
me
.
setTargetCoordinates
(
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
,
me
.
flightAltitude
);
console
.
log
(
"
distance to leader
"
,
distance
(
position
.
x
,
position
.
y
,
me
.
drone_dict
[
neighbor_id
].
latitude
,
me
.
drone_dict
[
neighbor_id
].
longitude
)
);
return
;
}
checkpointIndex
=
(
!
me
.
reverse
)
?
me
.
next_checkpoint
:
CHECKPOINT_LIST
.
length
-
me
.
next_checkpoint
-
1
;
if
(
!
me
.
direction_set
)
{
console
.
log
(
"
Going to Checkpoint
"
,
checkpointIndex
);
me
.
setTargetCoordinates
(
CHECKPOINT_LIST
[
checkpointIndex
].
latitude
,
CHECKPOINT_LIST
[
checkpointIndex
].
longitude
,
me
.
flightAltitude
);
me
.
direction_set
=
true
;
}
if
(
pointReached
(
me
,
CHECKPOINT_LIST
[
checkpointIndex
],
REGULAR_EPSILON
)
)
{
console
.
log
(
"
Reached Checkpoint
"
,
checkpointIndex
);
me
.
next_checkpoint
+=
1
;
me
.
next_checkpoint
%=
CHECKPOINT_LIST
.
length
;
me
.
direction_set
=
false
;
me
.
sendMsg
(
JSON
.
stringify
({
type
:
"
checkpoint
"
,
next_checkpoint
:
me
.
next_checkpoint
}));
}
return
;
}
if
(
me
.
going_to_rally
)
{
if
(
pointReached
(
me
,
RALLY_POINT
,
LOITER_ACCEPTANCE
))
{
console
.
log
(
"
Arrived to rally
"
);
me
.
going_to_rally
=
false
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
PARACHUTE_ALTITUDE
,
LOITER_RADIUS
);
}
return
;
}
if
(
!
me
.
parachute_altitude_reached
)
{
console
.
log
(
"
Altitude
"
,
me
.
getAltitudeAbs
());
if
(
Math
.
abs
(
me
.
getAltitudeAbs
()
-
PARACHUTE_ALTITUDE
)
<=
EPSILON_ALTITUDE
)
{
me
.
parachute_altitude_reached
=
true
;
}
return
;
}
if
(
!
me
.
parachute_yaw_reached
)
{
console
.
log
(
"
Yaw:
"
,
me
.
getYaw
());
if
(
Math
.
abs
(
me
.
getYaw
()
-
PARACHUTE_YAW
)
<=
YAW_EPSILON
)
{
me
.
parachute_yaw_reached
=
true
;
me
.
setTargetCoordinates
(
PARACHUTE_POINT
.
latitude
,
PARACHUTE_POINT
.
longitude
,
PARACHUTE_POINT
.
altitude
);
}
return
;
}
if
(
pointReached
(
me
,
PARACHUTE_POINT
,
PARACHUTE_EPSILON
))
{
deployParachute
(
me
);
}
};
me
.
onGetMsg
=
function
(
msg
)
{
var
msgDict
=
JSON
.
parse
(
msg
);
if
(
msgDict
.
hasOwnProperty
(
"
status
"
))
{
switch
(
msgDict
.
status
)
{
case
"
running
"
:
me
.
started
=
true
;
if
(
me
.
id
===
leaderId
(
me
))
{
me
.
sendMsg
(
JSON
.
stringify
(
{
id
:
me
.
id
,
inAir
:
true
,
state
:
"
Flying
"
,
type
:
"
state
"
}
));
}
break
;
case
"
stopped
"
:
if
(
me
.
id
===
me
.
id_list
[
0
])
{
me
.
landing
=
true
;
me
.
going_to_rally
=
true
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
me
.
flightAltitude
,
LOITER_RADIUS
);
}
break
;
default
:
console
.
log
(
"
Unknown status:
"
,
me
.
msgDict
.
status
);
}
return
;
}
switch
(
msgDict
.
type
)
{
case
"
state
"
:
if
(
msgDict
.
state
===
"
Landed
"
)
{
me
.
id_list
.
splice
(
me
.
id_list
.
indexOf
(
msgDict
.
id
),
1
);
if
(
me
.
id
===
me
.
id_list
[
0
])
{
me
.
landing
=
true
;
me
.
going_to_rally
=
true
;
me
.
loiter
(
RALLY_POINT
.
latitude
,
RALLY_POINT
.
longitude
,
me
.
flightAltitude
,
LOITER_RADIUS
);
}
}
break
;
default
:
console
.
log
(
"
Unknown message type:
"
+
msgDict
.
type
);
}
};
}(
console
,
me
));
v.js
0 → 100644
View file @
8d1d1ecb
/*
* In the script the swarm follows continuously a list of checkpoint while
* keeping the shape of a "V". This is a demo for the simulator.
*/
/*jslint nomen: true, indent: 2, maxerr: 3, maxlen: 80 */
/*global console, me*/
(
function
(
console
,
me
)
{
"
use strict
"
;
var
FLIGH_ALTITUDE
=
100
,
MINIMAL_DISTANCE
=
20
,
EPSILON
=
20
,
CHECKPOINT_LIST
=
[
{
altitude
:
585.1806861589965
,
latitude
:
45.64492790560583
,
longitude
:
14.25334942966329
},
{
altitude
:
589.8802607573035
,
latitude
:
45.64316335436476
,
longitude
:
14.26332880184475
},
{
altitude
:
608.6648153348965
,
latitude
:
45.64911917196595
,
longitude
:
14.26214792790128
},
{
altitude
:
606.1448368129072
,
latitude
:
45.64122685351364
,
longitude
:
14.26590493128597
},
{
altitude
:
630.0829598206344
,
latitude
:
45.64543355564817
,
longitude
:
14.27242391207985
},
{
altitude
:
616.1839898415284
,
latitude
:
45.6372792927328
,
longitude
:
14.27533492411138
},
{
altitude
:
598.0603137354178
,
latitude
:
45.64061299543953
,
longitude
:
14.26161958465814
},
{
altitude
:
607.1243119862851
,
latitude
:
45.64032340702919
,
longitude
:
14.2682896662383
}
],
R
=
6371
e3
;
function
exitOnFail
(
ret
,
msg
)
{
if
(
ret
)
{
console
.
log
(
msg
);
me
.
exit
(
1
);
}
}
function
deployParachute
(
drone
)
{
console
.
log
(
"
[DEMO] Deploying parachute...
"
);
me
.
sendMsg
(
"
landing
"
);
exitOnFail
(
drone
.
triggerParachute
(),
"
Failed to deploy parachute
"
);
me
.
exit
(
0
);
}
function
distance
(
lat1
,
lon1
,
lat2
,
lon2
)
{
var
la1
=
lat1
*
Math
.
PI
/
180
,
// la, lo in radians
la2
=
lat2
*
Math
.
PI
/
180
,
lo1
=
lon1
*
Math
.
PI
/
180
,
lo2
=
lon2
*
Math
.
PI
/
180
,
haversine_phi
=
Math
.
pow
(
Math
.
sin
((
la2
-
la1
)
/
2
),
2
),
sin_lon
=
Math
.
sin
((
lo2
-
lo1
)
/
2
),
h
=
haversine_phi
+
Math
.
cos
(
la1
)
*
Math
.
cos
(
la2
)
*
sin_lon
*
sin_lon
;
return
2
*
R
*
Math
.
asin
(
Math
.
sqrt
(
h
));
}
function
toRad
(
angle
)
{
return
Math
.
PI
*
angle
/
180
;
}
function
toDeg
(
angle
)
{
return
180
*
angle
/
Math
.
PI
;
}
function
constrain
(
input
,
min
,
max
)
{
return
(
input
>
max
)
?
max
:
(
input
<
min
)
?
min
:
input
;
}
//azimuthal projection
function
toLocalCoordinates
(
lat
,
lon
,
ref_sin_lat
,
ref_cos_lat
,
ref_lon_rad
)
{
var
lat_rad
=
toRad
(
lat
),
lon_rad
=
toRad
(
lon
),
sin_lat
=
Math
.
sin
(
lat_rad
),
cos_lat
=
Math
.
cos
(
lat_rad
),
cos_d_lon
=
Math
.
cos
(
lon_rad
-
ref_lon_rad
),
c
=
Math
.
acos
(
constrain
(
ref_sin_lat
*
sin_lat
+
ref_cos_lat
*
cos_lat
*
cos_d_lon
,
-
1
,
1
)),
k
=
(
Math
.
abs
(
c
)
>
0
)
?
(
c
/
Math
.
sin
(
c
))
:
1
,
mul
=
k
*
R
;
return
{
"
lat
"
:
mul
*
(
ref_cos_lat
*
sin_lat
-
ref_sin_lat
*
cos_lat
*
cos_d_lon
),
"
lon
"
:
mul
*
cos_lat
*
Math
.
sin
(
lon_rad
-
ref_lon_rad
)
};
}
function
toGlobalCoordinates
(
lat
,
lon
,
ref_sin_lat
,
ref_cos_lat
,
ref_lon_rad
)
{
var
x_rad
=
lat
/
R
,
y_rad
=
lon
/
R
,
c
=
Math
.
sqrt
(
x_rad
*
x_rad
+
y_rad
*
y_rad
),
sin_c
=
Math
.
sin
(
c
),
cos_c
=
Math
.
cos
(
c
),
lat_rad
=
Math
.
asin
(
cos_c
*
ref_sin_lat
+
(
x_rad
*
sin_c
*
ref_cos_lat
)
/
c
),
lon_rad
=
ref_lon_rad
+
Math
.
atan2
(
y_rad
*
sin_c
,
c
*
ref_cos_lat
*
cos_c
-
x_rad
*
ref_sin_lat
*
sin_c
);
return
{
"
lat
"
:
toDeg
(
lat_rad
),
"
lon
"
:
toDeg
(
lon_rad
)};
}
me
.
onStart
=
function
()
{
var
position
=
me
.
getCurrentPosition
(),
ref_lat_rad
=
toRad
(
position
.
x
);
me
.
direction_set
=
false
;
me
.
last_checkpoint_reached
=
false
;
me
.
next_checkpoint
=
0
;
me
.
start_altitude
=
me
.
getInitialAltitude
()
+
FLIGH_ALTITUDE
;
me
.
firstRun
=
true
;
me
.
ref_cos_lat
=
Math
.
cos
(
ref_lat_rad
);
me
.
ref_lon_rad
=
toRad
(
position
.
y
);
me
.
ref_sin_lat
=
Math
.
sin
(
ref_lat_rad
);
};
me
.
onUpdate
=
function
(
timestamp
)
{
var
leaderYawRad
;
if
(
me
.
firstRun
)
{
me
.
firstRun
=
false
;
me
.
secondRun
=
true
;
return
;
}
if
(
me
.
secondRun
)
{
me
.
leader_id
=
Math
.
trunc
(
me
.
drone_dict
.
length
/
2
);
me
.
is_leader
=
me
.
id
===
me
.
leader_id
;
me
.
secondRun
=
false
;
me
.
neighbour_id
=
(
me
.
id
<
me
.
leader_id
)
?
me
.
id
+
1
:
me
.
id
-
1
;
me
.
angleUpdate
=
((
me
.
id
<
me
.
leader_id
)
?
3
:
5
)
*
Math
.
PI
/
4
;
}
if
(
!
me
.
is_leader
)
{
leaderYawRad
=
toRad
(
me
.
drone_dict
[
me
.
neighbour_id
].
yaw
);
me
.
neighbor_local_coordinates
=
toLocalCoordinates
(
me
.
drone_dict
[
me
.
neighbour_id
].
latitude
,
me
.
drone_dict
[
me
.
neighbour_id
].
longitude
,
me
.
ref_sin_lat
,
me
.
ref_cos_lat
,
me
.
ref_lon_rad
);
me
.
next_coordinates
=
toGlobalCoordinates
(
me
.
neighbor_local_coordinates
.
lat
+
MINIMAL_DISTANCE
*
Math
.
sin
(
leaderYawRad
+
me
.
angleUpdate
),
me
.
neighbor_local_coordinates
.
lon
+
MINIMAL_DISTANCE
*
Math
.
cos
(
leaderYawRad
+
me
.
angleUpdate
),
me
.
ref_sin_lat
,
me
.
ref_cos_lat
,
me
.
ref_lon_rad
);
return
exitOnFail
(
me
.
setTargetCoordinates
(
me
.
next_coordinates
.
lat
,
me
.
next_coordinates
.
lon
,
me
.
drone_dict
[
me
.
neighbour_id
].
altitudeAbs
),
"
Failed to follow leader
"
);
}
if
(
!
me
.
direction_set
)
{
if
(
me
.
next_checkpoint
<
CHECKPOINT_LIST
.
length
)
{
exitOnFail
(
me
.
setTargetCoordinates
(
CHECKPOINT_LIST
[
me
.
next_checkpoint
].
latitude
,
CHECKPOINT_LIST
[
me
.
next_checkpoint
].
longitude
,
CHECKPOINT_LIST
[
me
.
next_checkpoint
].
altitude
+
FLIGH_ALTITUDE
),
"
Failed to set checkpoint coordinates
"
);
console
.
log
(
"
[DEMO] Going to Checkpoint
"
+
me
.
next_checkpoint
+
"
\n
"
);
}
me
.
direction_set
=
true
;
return
;
}
if
(
me
.
next_checkpoint
<
CHECKPOINT_LIST
.
length
)
{
me
.
current_position
=
me
.
getCurrentPosition
();
me
.
distance
=
distance
(
me
.
current_position
.
x
,
me
.
current_position
.
y
,
CHECKPOINT_LIST
[
me
.
next_checkpoint
].
latitude
,
CHECKPOINT_LIST
[
me
.
next_checkpoint
].
longitude
);
if
(
me
.
distance
>
EPSILON
)
{
console
.
log
(
"
Waiting for drone to get to destination (checkpoint
"
+
me
.
next_checkpoint
+
"
:
"
+
me
.
distance
+
"
m)
"
);
}
else
{
console
.
log
(
"
[DEMO] Reached Checkpoint
"
+
me
.
next_checkpoint
+
"
\n
"
);
me
.
next_checkpoint
+=
1
;
me
.
direction_set
=
false
;
}
return
;
}
deployParachute
(
me
);
};
me
.
onGetMsg
=
function
(
msg
)
{
me
.
msgDict
=
JSON
.
parse
(
msg
);
if
(
msg
===
"
landing
"
)
{
deployParachute
(
me
);
}
else
{
console
.
log
(
"
Unknown message:
"
,
msg
);
}
};
}(
console
,
me
));
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