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Larkin Heintzman
Drone ROS Packages
Commits
c2e326c8
Commit
c2e326c8
authored
Jan 11, 2022
by
Larkin Heintzman
Browse files
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plaths last flight push
parent
9325d37e
Changes
13
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13 changed files
with
1193 additions
and
227 deletions
+1193
-227
bus_driver.h
Onboard-SDK-ROS/include/dji_osdk_ros/bus_driver.h
+12
-1
qualisysPublisher.py
Onboard-SDK-ROS/scripts/qualisysPublisher.py
+2
-2
qualisysSpoofRemote.py
Onboard-SDK-ROS/scripts/qualisysSpoofRemote.py
+82
-0
dji_vehicle_node.cpp
Onboard-SDK-ROS/src/dji_osdk_ros/dji_vehicle_node.cpp
+4
-2
bus_driver.cpp
Onboard-SDK-ROS/src/dji_osdk_ros/samples/bus_driver.cpp
+352
-222
CMakeLists.txt
misson_controller/CMakeLists.txt
+208
-0
package.xml
misson_controller/package.xml
+74
-0
CMakeLists.txt
puredata/CMakeLists.txt
+207
-0
package.xml
puredata/package.xml
+71
-0
crushedPiano.wav
puredata/patches/crushedPiano.wav
+0
-0
drone-osc.pd
puredata/patches/drone-osc.pd
+84
-0
puredataLaunch.bash
puredata/scripts/puredataLaunch.bash
+4
-0
puredataPublisher.py
puredata/scripts/puredataPublisher.py
+93
-0
No files found.
Onboard-SDK-ROS/include/dji_osdk_ros/bus_driver.h
View file @
c2e326c8
...
...
@@ -111,7 +111,8 @@ ServiceAck obtainCtrlAuthority();
bool
takeoff
();
std
::
vector
<
float
>
relativePosition
(
float
x
,
float
y
,
float
z
,
float
yaw
);
void
relativeVelocity
(
float
x
,
float
y
,
float
z
,
float
yaw
,
float
dt
);
void
relativePosition
(
float
x
,
float
y
,
float
z
,
float
yaw
,
float
dt
);
float
applyRotationAngle
(
float
targetYaw
);
...
...
@@ -136,7 +137,17 @@ bool overwatchFunction(dji_osdk_ros::Overwatch::Request &req, dji_osdk_ros::Over
void
gpsPosCallback
(
const
sensor_msgs
::
NavSatFix
::
ConstPtr
&
msg
);
void
posFeedbackCallback
(
const
geometry_msgs
::
Transform
::
ConstPtr
&
msg
);
void
pdPositionCallback
(
const
geometry_msgs
::
Transform
::
ConstPtr
&
msg
);
void
posTrackingCallback
(
const
geometry_msgs
::
Transform
::
ConstPtr
&
msg
);
void
pdMaxSpeedCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
);
void
pdMaxYawSpeedCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
);
void
pdSpeedScaleCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
);
void
pdUpdateRateCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
);
void
pdDampingRateCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
);
void
pdFrequencyRateCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
);
void
pdAngleOffsetRateCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
);
#endif // MISSION_NODE_H
Onboard-SDK-ROS/scripts/qualisys
Feedback
.py
→
Onboard-SDK-ROS/scripts/qualisys
Publisher
.py
View file @
c2e326c8
...
...
@@ -14,8 +14,8 @@ def callback(data):
# we must remapp
#transform.translation = data.pose.position
transform
.
translation
.
x
=
data
.
pose
.
position
.
x
transform
.
translation
.
y
=
data
.
pose
.
position
.
z
transform
.
translation
.
z
=
data
.
pose
.
position
.
y
transform
.
translation
.
y
=
data
.
pose
.
position
.
y
transform
.
translation
.
z
=
data
.
pose
.
position
.
z
pub
.
publish
(
transform
)
...
...
Onboard-SDK-ROS/scripts/qualisysSpoofRemote.py
0 → 100755
View file @
c2e326c8
#!/usr/bin/python3
import
rospy
import
numpy
as
np
from
sensor_msgs.msg
import
NavSatFix
from
sensor_msgs.msg
import
Imu
from
std_msgs.msg
import
Float32
from
geometry_msgs.msg
import
PointStamped
from
geometry_msgs.msg
import
QuaternionStamped
from
geometry_msgs.msg
import
Transform
from
geometry_msgs.msg
import
Vector3
from
geometry_msgs.msg
import
Quaternion
import
math
from
pyproj
import
Transformer
class
QualisysSpoof
():
def
__init__
(
self
):
rospy
.
init_node
(
"qualisysSpoof"
)
# zero zero of fake qualisys frame
self
.
anchorPoint
=
rospy
.
get_param
(
"~anchorPoint"
)
rospy
.
Subscriber
(
"dji_osdk_ros/gps_position"
,
NavSatFix
,
self
.
gpsCallback
,
queue_size
=
1
)
rospy
.
Subscriber
(
"dji_osdk_ros/attitude"
,
QuaternionStamped
,
self
.
rotCallback
,
queue_size
=
1
)
# rospy.Subscriber("dji_osdk_ros/height_above_takeoff", Float32, self.heightCallback, queue_size = 1)
# standing in for the feedback qualisys stream
self
.
posePublisher
=
rospy
.
Publisher
(
"feedback"
,
Transform
,
queue_size
=
1
)
self
.
quat
=
Quaternion
()
self
.
transform
=
Transform
()
self
.
startHeightSet
=
False
self
.
startHeight
=
0.0
# self.height = 0.0
def
point_rotation
(
self
,
origin
,
pt
,
ang
):
# returns the pt rotated about the origin by ang (ang in degrees)
c
=
math
.
cos
(
math
.
radians
(
ang
))
s
=
math
.
sin
(
math
.
radians
(
ang
))
# translate to origin
pt_temp
=
[
pt
[
0
]
-
origin
[
0
],
pt
[
1
]
-
origin
[
1
]]
pt_spun
=
[
pt_temp
[
0
]
*
c
-
pt_temp
[
1
]
*
s
,
pt_temp
[
0
]
*
s
+
pt_temp
[
1
]
*
c
]
# translate back to frame
pt_spun
=
[
pt_spun
[
0
]
+
origin
[
0
],
pt_spun
[
1
]
+
origin
[
1
]]
return
pt_spun
def
meters2lat_lon
(
self
,
meters_point
):
# returns point converted to lat lon from meters coordinate system
transformer
=
Transformer
.
from_crs
(
3857
,
4326
)
latlon_point
=
transformer
.
transform
(
meters_point
[
0
],
meters_point
[
1
])
return
latlon_point
def
lat_lon2meters
(
self
,
latlon_point
):
# returns point converted to meters from lat lon coordinate system
transformer
=
Transformer
.
from_crs
(
4326
,
3857
)
meters_point
=
transformer
.
transform
(
latlon_point
[
0
],
latlon_point
[
1
])
return
meters_point
def
rotCallback
(
self
,
data
):
self
.
quat
=
data
.
quaternion
def
gpsCallback
(
self
,
data
):
# convert and compare against home point
apMeters
=
self
.
lat_lon2meters
([
self
.
anchorPoint
[
0
],
self
.
anchorPoint
[
1
]])
cpMeters
=
self
.
lat_lon2meters
([
data
.
latitude
,
data
.
longitude
])
currentOffset
=
[
cpMeters
[
0
]
-
apMeters
[
0
],
cpMeters
[
1
]
-
apMeters
[
1
]]
# rotate current offset by a bit
currentOffset
=
self
.
point_rotation
([
0
,
0
],
currentOffset
,
rospy
.
get_param
(
"~angleOffset"
));
# save init height
if
(
not
self
.
startHeightSet
):
self
.
startHeightSet
=
True
self
.
startHeight
=
data
.
altitude
# performing dark magics
self
.
transform
.
translation
.
x
=
currentOffset
[
1
]
self
.
transform
.
translation
.
y
=
currentOffset
[
0
]
self
.
transform
.
translation
.
z
=
data
.
altitude
-
self
.
startHeight
self
.
transform
.
rotation
=
self
.
quat
self
.
posePublisher
.
publish
(
self
.
transform
)
if
__name__
==
'__main__'
:
qualer
=
QualisysSpoof
()
rospy
.
spin
()
Onboard-SDK-ROS/src/dji_osdk_ros/dji_vehicle_node.cpp
View file @
c2e326c8
...
...
@@ -516,7 +516,7 @@ bool VehicleNode::initDataSubscribeFromFC()
int
nTopic100Hz
=
topicList100Hz
.
size
();
if
(
ptr_wrapper_
->
initPackageFromTopicList
(
static_cast
<
int
>
(
SubscribePackgeIndex
::
PACKAGE_ID_100HZ
),
nTopic100Hz
,
topicList100Hz
.
data
(),
1
,
10
0
))
topicList100Hz
.
data
(),
1
,
5
0
))
{
ack
=
ptr_wrapper_
->
startPackage
(
static_cast
<
int
>
(
SubscribePackgeIndex
::
PACKAGE_ID_100HZ
),
WAIT_TIMEOUT
);
if
(
ACK
::
getError
(
ack
))
...
...
@@ -663,8 +663,10 @@ bool VehicleNode::initDataSubscribeFromFC()
topicList400Hz
.
push_back
(
Telemetry
::
TOPIC_HARD_SYNC
);
int
nTopic400Hz
=
topicList400Hz
.
size
();
// if (ptr_wrapper_->initPackageFromTopicList(static_cast<int>(SubscribePackgeIndex::PACKAGE_ID_400HZ), nTopic400Hz,
// topicList400Hz.data(), 1, 400))
if
(
ptr_wrapper_
->
initPackageFromTopicList
(
static_cast
<
int
>
(
SubscribePackgeIndex
::
PACKAGE_ID_400HZ
),
nTopic400Hz
,
topicList400Hz
.
data
(),
1
,
40
0
))
topicList400Hz
.
data
(),
1
,
5
0
))
{
ack
=
ptr_wrapper_
->
startPackage
(
static_cast
<
int
>
(
SubscribePackgeIndex
::
PACKAGE_ID_400HZ
),
WAIT_TIMEOUT
);
if
(
ACK
::
getError
(
ack
))
...
...
Onboard-SDK-ROS/src/dji_osdk_ros/samples/bus_driver.cpp
View file @
c2e326c8
...
...
@@ -51,13 +51,17 @@ ros::ServiceClient waypoint_action_client;
ros
::
ServiceClient
flight_control_client
;
ros
::
ServiceClient
mission_waypoint_client
;
ros
::
ServiceClient
obtain_ctrl_authority_client
;
ros
::
Publisher
syncPub
;
// thing to publish to sync topic "positionSync"
// need to take another look at synchronization...
// ros::Publisher syncPub; // thing to publish to sync topic "positionSync"
sensor_msgs
::
NavSatFix
gps_pos
;
// gps position from drone
geometry_msgs
::
Transform
ex_pos
;
// position from external source (qualisys or some such)
geometry_msgs
::
Transform
track_pos
;
// position from external source (qualisys or some such)
geometry_msgs
::
Transform
previous_ex_pos
;
// position from external source (qualisys or some such)
geometry_msgs
::
Transform
previous_track_pos
;
// position from external source (qualisys or some such)
geometry_msgs
::
Transform
track_pos
;
// target position
geometry_msgs
::
Transform
previous_ex_pos
;
geometry_msgs
::
Transform
previous_track_pos
;
geometry_msgs
::
Transform
pd_pos
;
// desired pose from pd relative to qual center (only x on rotation)
std
::
vector
<
float
>
expectedVel
;
// expected position after applying relative position move
float
feedbackYaw
;
// yaw as measured by pos ref
float
feedbackPitch
;
// pitch as measured by pos ref
...
...
@@ -65,7 +69,7 @@ float feedbackRoll; // roll as measured by pos ref
float
trackingYaw
;
// yaw to track
float
trackingPitch
;
// pitch to track
float
trackingRoll
;
// roll to track
int
calibrationWindow
=
25
;
// the last _ position calls that are included in coordinate system calibration
int
calibrationWindow
=
3
;
// the last _ position calls that are included in coordinate system calibration
std
::
vector
<
float
>
calibrationWindowValues
;
float
angleOffset
;
float
controlLoopTime
;
...
...
@@ -78,12 +82,25 @@ bool rotationMatrixCalibratedFlag = false;
bool
gps_home_flag
=
false
;
bool
pos_home_flag
=
false
;
bool
positionMissionFlag
=
false
;
bool
waypointMissionFlag
=
false
;
bool
positionPlaybackParam
=
false
;
bool
localMissionFlag
=
false
;
// whether running position mission currently
bool
gpsMissionFlag
=
false
;
// whether running gps mission currently
string
missionTypeParam
;
ros
::
Subscriber
gps_pos_subscriber
;
ros
::
Subscriber
pos_feedback_subscriber
;
ros
::
Subscriber
pos_tracking_subscriber
;
ros
::
Subscriber
pd_position_subscriber
;
ros
::
Subscriber
pd_heading_subscriber
;
// temp subscribers to pick up puredata parameter information, will be removed once the right parameters are settled on
ros
::
Subscriber
pd_parameter_MinSpeed_subscriber
;
ros
::
Subscriber
pd_parameter_MaxSpeed_subscriber
;
ros
::
Subscriber
pd_parameter_MaxYawSpeed_subscriber
;
ros
::
Subscriber
pd_parameter_SpeedScale_subscriber
;
ros
::
Subscriber
pd_parameter_UpdateRate_subscriber
;
ros
::
Subscriber
pd_parameter_Damping_subscriber
;
ros
::
Subscriber
pd_parameter_Frequency_subscriber
;
ros
::
Subscriber
pd_parameter_AngleOffset_subscriber
;
int
droneId
;
// stupid but will work for now
int
waypointMissionUpdateCounter
=
0
;
// counts iterations before we check waypoints again
...
...
@@ -96,15 +113,14 @@ int waypointNumber;
int
currentWaypoint
=
0
;
// how many waypoints have we reached
long
double
initialWaypointDistance
;
// distance to first waypoint
long
double
initialPositionDistance
;
// distance to first position
double
baseSpeedParam
;
double
minSpeedParam
;
double
waypointSpeedParam
;
double
positionThresholdParam
;
double
angleOffsetParam
;
double
maxSpeedParam
;
double
speedScalarParam
;
double
minYawSpeedParam
;
double
maxYawSpeedParam
;
// inverse controller variables
ros
::
WallTime
previousWallTime
;
double
dt
;
double
damping
;
double
frequency
;
...
...
@@ -119,10 +135,6 @@ double g;
// converting degrees to radians
long
double
toRadians
(
const
long
double
degree
)
{
// cmath library in C++
// defines the constant
// M_PI as the value of
// pi accurate to 1e-30
long
double
one_deg
=
(
M_PI
)
/
180
;
return
(
one_deg
*
degree
);
}
...
...
@@ -147,8 +159,6 @@ float eucDistance(std::vector<float> a, std::vector<float> b)
long
double
gpsDistance
(
long
double
lat1
,
long
double
long1
,
long
double
lat2
,
long
double
long2
)
{
// Convert the latitudes
// and longitudes
// from degree to radians.
lat1
=
toRadians
(
lat1
);
long1
=
toRadians
(
long1
);
lat2
=
toRadians
(
lat2
);
...
...
@@ -164,10 +174,7 @@ long double gpsDistance(long double lat1, long double long1, long double lat2, l
ans
=
2
*
asin
(
sqrt
(
ans
));
// Radius of Earth in
// Kilometers, R = 6371
// Use R = 3956 for miles
long
double
R
=
6371
;
long
double
R
=
6371
;
// radius of earth
// Calculate the result
ans
=
ans
*
R
;
...
...
@@ -194,14 +201,12 @@ std::vector<std::vector<float>> rotateAxisAngle(std::vector<float> u, float angl
return
rotationMatrix
;
}
// Function that return
// dot product of two vector array.
float
dotProduct
(
std
::
vector
<
float
>
vect_A
,
std
::
vector
<
float
>
vect_B
)
{
float
product
=
0
;
int
vectorSize
=
vect_A
.
size
();
// both vectors must be of same length
// Loop for calculate cot product
for
(
int
i
=
0
;
i
<
vectorSize
;
i
++
)
product
=
product
+
vect_A
[
i
]
*
vect_B
[
i
];
...
...
@@ -217,7 +222,6 @@ float flatAngleBetween(std::vector<float> a, std::vector<float> b)
return
normalizeAngle
(
acosf
(
dotProd
/
(
Magnitude3
(
a
)
*
Magnitude3
(
b
))));
}
// Function to find
// cross product of two vector array.
std
::
vector
<
float
>
crossProduct
(
std
::
vector
<
float
>
vect_A
,
std
::
vector
<
float
>
vect_B
)
{
...
...
@@ -251,10 +255,7 @@ std::vector<float> MatrixMultiply(std::vector <std::vector<float>> a, std::vecto
const
int
n
=
a
.
size
();
// a cols
const
int
m
=
a
[
0
].
size
();
// a rows
std
::
vector
<
float
>
c
(
n
);
// the PAIN
// ROS_INFO(" rotation matrix calc:");
for
(
auto
k
=
0
;
k
<
m
;
++
k
)
// row loop
{
for
(
auto
i
=
0
;
i
<
n
;
++
i
)
// col loop
...
...
@@ -267,32 +268,38 @@ std::vector<float> MatrixMultiply(std::vector <std::vector<float>> a, std::vecto
return
c
;
}
std
::
vector
<
std
::
vector
<
float
>>
rotateAlign
(
std
::
vector
<
float
>
v1
,
std
::
vector
<
float
>
v2
)
{
std
::
vector
<
float
>
axis
=
normalizeVector
(
crossProduct
(
v1
,
v2
));
float
dotProd
=
dotProduct
(
normalizeVector
(
v1
),
normalizeVector
(
v2
));
if
(
dotProd
<
-
1.0
)
{
dotProd
=
-
1.0
;
}
else
if
(
dotProd
>
1.0
)
{
dotProd
=
1.0
;
}
poseRotationRadians
=
acosf
(
dotProd
);
std
::
vector
<
std
::
vector
<
float
>>
result
=
rotateAxisAngle
(
axis
,
poseRotationRadians
);
// returns rotation matrix
// std::vector<std::vector<float>> rotateAlign(std::vector<float> v1, std::vector<float> v2)
// {
// std::vector<float> axis = normalizeVector(crossProduct(v1, v2));
// float dotProd = dotProduct(normalizeVector(v1), normalizeVector(v2));
// if (dotProd < -1.0)
// {
// dotProd = -1.0;
// }
// else if (dotProd > 1.0)
// {
// dotProd = 1.0;
// }
// poseRotationRadians = acosf(dotProd);
// std::vector<std::vector<float>> result = rotateAxisAngle(axis, poseRotationRadians); // returns rotation matrix
//
// ROS_INFO("axis of rotation: (%f, %f, %f)", axis[0], axis[1], axis[2]);
// ROS_INFO("dot product: (%f)", dotProd);
// ROS_INFO("angle rad: (%f)", poseRotationRadians);
// return result;
// }
ROS_INFO
(
"axis of rotation: (%f, %f, %f)"
,
axis
[
0
],
axis
[
1
],
axis
[
2
]);
ROS_INFO
(
"dot product: (%f)"
,
dotProd
);
ROS_INFO
(
"angle rad: (%f)"
,
poseRotationRadians
);
return
result
;
void
pdPositionCallback
(
const
geometry_msgs
::
Transform
::
ConstPtr
&
msg
)
{
pd_pos
=
*
msg
;
// annnnnd thats it folks
}
// for those times where we actually fly outside lmao
void
gpsPosCallback
(
const
sensor_msgs
::
NavSatFix
::
ConstPtr
&
msg
)
{
gps_pos
=
*
msg
;
if
(
!
waypoint
MissionFlag
)
if
(
!
gps
MissionFlag
)
{
return
;
// peace out if not running mission
}
...
...
@@ -338,7 +345,7 @@ void gpsPosCallback(const sensor_msgs::NavSatFix::ConstPtr& msg)
// now update sync topic with progress through waypoints
std_msgs
::
Float32
syncUpdate
;
syncUpdate
.
data
=
static_cast
<
float32_t
>
(
currentWaypoint
)
+
static_cast
<
float32_t
>
(
static_cast
<
float32_t
>
(
1
)
-
progressDistance
/
nextWaypointDistance
);
syncPub
.
publish
(
syncUpdate
);
//
syncPub.publish(syncUpdate);
if
(
progressDistance
<
tolerance
)
{
...
...
@@ -359,6 +366,14 @@ void posFeedbackCallback(const geometry_msgs::Transform::ConstPtr& msg)
previous_ex_pos
=
ex_pos
;
ex_pos
=
*
msg
;
// alllllways load the message
// ROS_INFO("Current feedback postion %f, %f, %f", ex_pos.translation.x, ex_pos.translation.y, ex_pos.translation.z);
//
// // for fuckin symetry i guess
// if (!localMissionFlag)
// {
// return; // peace out if not running mission
// }
// FINE ill DO it MYself all ALONE
feedbackYaw
=
atan2
(
2.0
*
(
ex_pos
.
rotation
.
x
*
ex_pos
.
rotation
.
y
+
ex_pos
.
rotation
.
z
*
ex_pos
.
rotation
.
w
),
1
-
2.0
*
(
ex_pos
.
rotation
.
y
*
ex_pos
.
rotation
.
y
+
ex_pos
.
rotation
.
z
*
ex_pos
.
rotation
.
z
));
feedbackPitch
=
asin
(
2.0
*
(
ex_pos
.
rotation
.
x
*
ex_pos
.
rotation
.
z
-
ex_pos
.
rotation
.
w
*
ex_pos
.
rotation
.
y
));
...
...
@@ -367,22 +382,24 @@ void posFeedbackCallback(const geometry_msgs::Transform::ConstPtr& msg)
void
posTrackingCallback
(
const
geometry_msgs
::
Transform
::
ConstPtr
&
msg
)
{
previous_track_pos
=
track_pos
;
track_pos
=
*
msg
;
// FINE ill DO it MYself all ALONE
// // for fuckin symetry i guess
// if (!localMissionFlag)
// {
// return; // peace out if not running mission
// }
trackingYaw
=
atan2
(
2.0
*
(
track_pos
.
rotation
.
x
*
track_pos
.
rotation
.
y
+
track_pos
.
rotation
.
z
*
track_pos
.
rotation
.
w
),
1
-
2.0
*
(
track_pos
.
rotation
.
y
*
track_pos
.
rotation
.
y
+
track_pos
.
rotation
.
z
*
track_pos
.
rotation
.
z
));
trackingPitch
=
asin
(
2.0
*
(
track_pos
.
rotation
.
x
*
track_pos
.
rotation
.
z
-
track_pos
.
rotation
.
w
*
track_pos
.
rotation
.
y
));
trackingRoll
=
atan2
(
2.0
*
(
track_pos
.
rotation
.
x
*
track_pos
.
rotation
.
w
+
track_pos
.
rotation
.
y
*
track_pos
.
rotation
.
z
),
1
-
2.0
*
(
track_pos
.
rotation
.
z
*
track_pos
.
rotation
.
z
+
track_pos
.
rotation
.
w
*
track_pos
.
rotation
.
w
));
}
bool
setupWaypointMission
(
int
responseTimeout
)
{
ros
::
spinOnce
();
// ROS_INFO();
while
(
!
ros
::
param
::
has
(
"/robot_list/robot_"
+
to_string
(
droneId
)
+
"/numWaypoints"
))
{
ROS_INFO
(
"waiting for waypoints to load..."
);
...
...
@@ -432,8 +449,8 @@ bool runWaypointMission()
return
false
;
}
waypoint
MissionFlag
=
true
;
position
MissionFlag
=
false
;
gps
MissionFlag
=
true
;
local
MissionFlag
=
false
;
return
true
;
}
...
...
@@ -441,26 +458,24 @@ bool runWaypointMission()
bool
runPositionMission
()
{
std
::
vector
<
float
>
velocityCommand
{
0.0
,
0.0
,
0.0
};
ros
::
Rate
updateRate
(
updateRateParam
);
// update period for topics/commands
positionMissionFlag
=
tru
e
;
localMissionFlag
=
true
;
gpsMissionFlag
=
fals
e
;
int
currentPositionIndex
=
0
;
int
numPositions
;
ros
::
param
::
get
(
"/robot_list/robot_"
+
to_string
(
droneId
)
+
"/numPositions"
,
numPositions
);
while
(
position
MissionFlag
&&
ros
::
ok
())
while
(
local
MissionFlag
&&
ros
::
ok
())
{
ros
::
Rate
updateRate
(
updateRateParam
);
// let topics update
ros
::
spinOnce
();
dt
=
(
ros
::
WallTime
::
now
()
-
previousWallTime
).
toNSec
()
*
1e-9
;
g
=
1
/
(
1
+
kd
*
dt
+
kp
*
dt
*
dt
);
dt
=
controlLoopTime
;
g
=
1.0
/
(
1.0
+
kd
*
dt
+
kp
*
dt
*
dt
);
ksg
=
kp
*
g
;
kdg
=
(
kd
+
kp
*
dt
)
*
g
;
previousWallTime
=
ros
::
WallTime
::
now
();
std
::
vector
<
float
>
currentPos
{
...
...
@@ -468,6 +483,7 @@ bool runPositionMission()
static_cast
<
float
>
(
ex_pos
.
translation
.
y
),
static_cast
<
float
>
(
ex_pos
.
translation
.
z
)
};
ROS_INFO
(
"Current postion %f, %f, %f"
,
currentPos
[
0
],
currentPos
[
1
],
currentPos
[
2
]);
std
::
vector
<
float
>
currentVel
{
...
...
@@ -480,16 +496,17 @@ bool runPositionMission()
std
::
vector
<
float
>
targetVel
;
float
targetYaw
;
// check expected velocity verses actual velocity
if
(
Magnitude3
(
velocityCommand
)
!=
0.0
&&
Magnitude3
(
currentVel
)
!=
0.0
)
{
float
ang
=
flatAngleBetween
(
velocityCommand
,
currentVel
);
updateAngleScaler
(
ang
);
ROS_INFO
(
"new angle discrepancy!: %f"
,
angleOffset
);
}
// wip, just align w external reference
// check expected velocity verses actual velocity
// if (Magnitude3(velocityCommand) != 0.0 && Magnitude3(currentVel) != 0.0)
// {
// float ang = flatAngleBetween(velocityCommand, currentVel);
// updateAngleScaler(ang);
// ROS_INFO("new angle discrepancy: %f", angleOffset);
// }
// next depends on what mode we're in ------------------------------------
if
(
positionPlaybackParam
)
if
(
missionTypeParam
.
compare
(
"tracking"
)
==
0
)
{
targetPos
=
std
::
vector
<
float
>
{
...
...
@@ -507,7 +524,19 @@ bool runPositionMission()
targetYaw
=
trackingYaw
;
}
else
else
if
(
missionTypeParam
.
compare
(
"puredata"
)
==
0
)
{
// let pure data handle positioning, we just load from topic
targetPos
=
std
::
vector
<
float
>
{
static_cast
<
float
>
(
pd_pos
.
translation
.
x
),
static_cast
<
float
>
(
pd_pos
.
translation
.
y
),
static_cast
<
float
>
(
pd_pos
.
translation
.
z
)
};
targetYaw
=
pd_pos
.
rotation
.
x
;
targetVel
=
std
::
vector
<
float
>
{
0.0
,
0.0
,
0.0
};
}
else
if
(
missionTypeParam
.
compare
(
"points"
)
==
0
)
{
std
::
vector
<
float
>
tempPos
;
ros
::
param
::
get
(
"/robot_list/robot_"
+
to_string
(
droneId
)
+
"/positions/position_"
+
to_string
(
currentPositionIndex
),
tempPos
);
...
...
@@ -517,27 +546,26 @@ bool runPositionMission()
tempPos
[
2
],
tempPos
[
3
]
};
//----------------------------------
targetVel
=
std
::
vector
<
float
>
{
0.0
,
0.0
,
0.0
};
targetYaw
=
normalizeAngle
((
M_PI
/
180.0
)
*
tempPos
[
4
]);
//----------------------------------
targetYaw
=
normalizeAngle
((
M_PI
/
180.0
)
*
tempPos
[
4
])
+
angleOffsetParam
;
// check if we're close to position
float
checkDist
=
eucDistance
(
currentPos
,
targetPos
);
if
(
checkDist
<=
0.2
)
//&& abs(currentYaw - targetYaw) <= 0.1) // close ish
if
(
checkDist
<=
positionThresholdParam
)
//&& abs(currentYaw - targetYaw) <= 0.1) // close ish
{
currentPositionIndex
+=
1
;
// go to next position
}
if
(
currentPositionIndex
>=
numPositions
)
{
position
MissionFlag
=
false
;
local
MissionFlag
=
false
;
}
}
float
currentYaw
=
feedbackYaw
;
ROS_INFO
(
"Current postion %f, %f, %f"
,
currentPos
[
0
],
currentPos
[
1
],
currentPos
[
2
]);
ROS_INFO
(
"Target position %f, %f, %f"
,
targetPos
[
0
],
targetPos
[
1
],
targetPos
[
2
]);
ROS_INFO
(
"Target velocity %f, %f, %f"
,
targetVel
[
0
],
targetVel
[
1
],
targetVel
[
2
]);
ROS_INFO
(
"Target yaw: %f"
,
targetYaw
);
ROS_INFO
(
"Current yaw: %f"
,
currentYaw
);
ROS_INFO
(
"Elapsed frame time: %f"
,
static_cast
<
float
>
(
dt
));
...
...
@@ -548,29 +576,136 @@ bool runPositionMission()
std
::
vector
<
float
>
force
{
// using commanded velocity instead of actual
static_cast
<
float
>
((
(
targetPos
[
0
]
-
currentPos
[
0
])
*
ksg
+
(
targetVel
[
0
]
-
velocityCommand
[
0
])
*
kdg
)
*
speedScalarParam
),
static_cast
<
float
>
((
(
targetPos
[
1
]
-
currentPos
[
1
])
*
ksg
+
(
targetVel
[
1
]
-
velocityCommand
[
1
])
*
kdg
)
*
speedScalarParam
),
static_cast
<
float
>
((
(
targetPos
[
2
]
-
currentPos
[
2
])
*
ksg
+
(
targetVel
[
2
]
-
velocityCommand
[
2
])
*
kdg
)
*
speedScalarParam
)
static_cast
<
float
>
((
targetPos
[
0
]
-
currentPos
[
0
])
*
ksg
+
(
targetVel
[
0
]
-
velocityCommand
[
0
])
*
kdg
),
static_cast
<
float
>
((
targetPos
[
1
]
-
currentPos
[
1
])
*
ksg
+
(
targetVel
[
1
]
-
velocityCommand
[
1
])
*
kdg
),
static_cast
<
float
>
((
targetPos
[
2
]
-
currentPos
[
2
])
*
ksg
+
(
targetVel
[
2
]
-
velocityCommand
[
2
])
*
kdg
)
};
ROS_INFO
(
"target velocity: %f, %f, %f"
,
targetVel
[
0
],
targetVel
[
1
],
targetVel
[
2
]);
ROS_INFO
(
"current velocity: %f, %f, %f"
,
currentVel
[
0
],
currentVel
[
1
],
currentVel
[
2
]);
velocityCommand
=
std
::
vector
<
float
>
{
velocityCommand
[
0
]
+
dt
*
force
[
0
],
velocityCommand
[
1
]
+
dt
*
force
[
1
],
velocityCommand
[
2
]
+
dt
*
force
[
2
]};
// velocityCommand = MatrixMultiply(rotateAxisAngle(std::vector<float> {0.0, 0.0, 1.0}, angleOffset), velocityCommand);
force
=
MatrixMultiply
(
rotateAxisAngle
(
std
::
vector
<
float
>
{
0.0
,
0.0
,
1.0
},
angleOffsetParam
),
force
);
velocityCommand
=
std
::
vector
<
float
>
{
velocityCommand
[
0
]
*
speedScalarParam
+
dt
*
force
[
0
],
velocityCommand
[
1
]
*
speedScalarParam
+
dt
*
force
[
1
],
velocityCommand
[
2
]
*
speedScalarParam
+
dt
*
force
[
2
]};
if
(
Magnitude3
(
velocityCommand
)
>
maxSpeedParam
)
{
velocityCommand
=
normalizeVector
(
velocityCommand
);
velocityCommand
=
std
::
vector
<
float
>
{
maxSpeedParam
*
velocityCommand
[
0
],
maxSpeedParam
*
velocityCommand
[
1
],
maxSpeedParam
*
velocityCommand
[
2
]};
ROS_INFO
(
"normalizing velocity command..."
);
}
velocityCommand
=
MatrixMultiply
(
rotateAxisAngle
(
std
::
vector
<
float
>
{
0.0
,
0.0
,
1.0
},
angleOffset
),
velocityCommand
);
ROS_INFO
(
"calling vel command %f, %f, %f"
,
velocityCommand
[
0
],
velocityCommand
[
1
],
velocityCommand
[
2
]);
expectedVel
=
relativePosition
(
velocityCommand
[
0
],
velocityCommand
[
1
],
velocityCommand
[
2
],
yawCommand
);
relativeVelocity
(
velocityCommand
[
0
],
velocityCommand
[
1
],
velocityCommand
[
2
],
yawCommand
,
dt
);
updateRate
.
sleep
();
}
return
true
;
}
void
relativeVelocity
(
float
x
,
float
y
,
float
z
,
float
yaw
,
float
dt
)
{
// convert relative position to velocity command
std
::
vector
<
float
>
posVec
{
x
,
y
,
z
};
float
totalSpeed
=
Magnitude3
(
posVec
);
float
speed
;
// float dt = controlLoopTime*1000.0;
if
(
totalSpeed
>
maxSpeedParam
)
{
speed
=
maxSpeedParam
;
}
else
{
speed
=
totalSpeed
;
}
std
::
vector
<
float
>
velDir
=
normalizeVector
(
posVec
);
std
::
vector
<
float
>
velVec
=
{
velDir
[
0
]
*
speed
,
velDir
[
1
]
*
speed
,
velDir
[
2
]
*
speed
};
dji_osdk_ros
::
FlightTaskControl
flightTaskControl
;
dji_osdk_ros
::
JoystickParams
joystickParams
;
joystickParams
.
x
=
velVec
[
0
];
joystickParams
.
y
=
velVec
[
1
];
joystickParams
.
z
=
velVec
[
2
];
if
(
abs
(
yaw
)
>
maxYawSpeedParam
)
{
if
(
yaw
<
0
)
{
yaw
=
-
maxYawSpeedParam
;
}
else
{
yaw
=
maxYawSpeedParam
;
}
}
joystickParams
.
yaw
=
(
180.0
/
M_PI
)
*
yaw
;
ROS_INFO
(
"rel vel: (yaw rate: %fdeg/s, speed: %fm/s, over %fsec, going %fm)"
,
joystickParams
.
yaw
,
speed
,
dt
,
totalSpeed
);
ROS_INFO
(
"---------------
\n
"
);
flightTaskControl
.
request
.
task
=
dji_osdk_ros
::
FlightTaskControl
::
Request
::
TASK_VELOCITY_AND_YAWRATE_CONTROL
;
flightTaskControl
.
request
.
joystickCommand
=
joystickParams
;
flightTaskControl
.
request
.
velocityControlTimeMs
=
dt
;
flightTaskControl
.
request
.
posThresholdInM
=
0.1
;
flightTaskControl
.
request
.
yawThresholdInDeg
=
1
;
flight_control_client
.
call
(
flightTaskControl
);
// actually waits for drone to "reach" position
// return flightTaskControl.response.result;
// return std::vector<float> {(dt)*velVec[0], (dt)*velVec[1], (dt)*velVec[2]};
return
;
}
void
relativePosition
(
float
x
,
float
y
,
float
z
,
float
yaw
,
float
dt
)
{
// // convert relative position to velocity command
std
::
vector
<
float
>
posVec
{
x
,
y
,
z
};
float
totalDist
=
Magnitude3
(
posVec
);
// float speed;
// // float dt = controlLoopTime*1000.0;
// if ((totalDist/dt) > maxSpeedParam)
// {
// speed = maxSpeedParam;
// }
// else
// {
// speed = totalDist/dt;
// }
//
// std::vector<float> velDir = normalizeVector(posVec);
// std::vector<float> velVec = {velDir[0]*speed, velDir[1]*speed, velDir[2]*speed};
//
dji_osdk_ros
::
FlightTaskControl
flightTaskControl
;
dji_osdk_ros
::
JoystickParams
joystickParams
;
joystickParams
.
x
=
x
;
joystickParams
.
y
=
y
;
joystickParams
.
z
=
z
;
//
// if (abs(yaw) > maxYawSpeedParam)
// {
// if (yaw < 0)
// {
// yaw = -maxYawSpeedParam;
// }
// else
// {
// yaw = maxYawSpeedParam;
// }
// }
joystickParams
.
yaw
=
(
180.0
/
M_PI
)
*
yaw
;
ROS_INFO
(
"rel pos: (yaw rate: %fdeg/s, speed: %fm/s, over %fsec, going %fm)"
,
joystickParams
.
yaw
,
totalDist
/
dt
,
dt
,
totalDist
);
ROS_INFO
(
"---------------
\n
"
);
flightTaskControl
.
request
.
task
=
dji_osdk_ros
::
FlightTaskControl
::
Request
::
TASK_POSITION_AND_YAW_CONTROL
;
flightTaskControl
.
request
.
joystickCommand
=
joystickParams
;
flightTaskControl
.
request
.
velocityControlTimeMs
=
dt
;
flightTaskControl
.
request
.
posThresholdInM
=
0.1
;
flightTaskControl
.
request
.
yawThresholdInDeg
=
1
;
flight_control_client
.
call
(
flightTaskControl
);
// actually waits for drone to "reach" position
// return flightTaskControl.response.result;
// return std::vector<float> {(dt)*velVec[0], (dt)*velVec[1], (dt)*velVec[2]};
return
;
}
void
setWaypointDefaults
(
WayPointSettings
*
wp
)
{
wp
->
damping
=
0.25
;
...
...
@@ -590,8 +725,8 @@ void setWaypointDefaults(WayPointSettings* wp)
void
setWaypointInitDefaults
(
dji_osdk_ros
::
MissionWaypointTask
&
waypointTask
)
{
waypointTask
.
velocity_range
=
base
SpeedParam
;
waypointTask
.
idle_velocity
=
base
SpeedParam
;
waypointTask
.
velocity_range
=
waypoint
SpeedParam
;
waypointTask
.
idle_velocity
=
waypoint
SpeedParam
;
waypointTask
.
action_on_finish
=
dji_osdk_ros
::
MissionWaypointTask
::
FINISH_NO_ACTION
;
waypointTask
.
mission_exec_times
=
1
;
waypointTask
.
yaw_mode
=
dji_osdk_ros
::
MissionWaypointTask
::
YAW_MODE_RC
;
...
...
@@ -684,10 +819,6 @@ ServiceAck missionAction(DJI::OSDK::DJI_MISSION_TYPE type,
missionWpAction
.
response
.
cmd_set
,
missionWpAction
.
response
.
cmd_id
,
missionWpAction
.
response
.
ack_data
};
// switch (type)
// {
// case DJI::OSDK::WAYPOINT:
// }
}
bool
takeoff
()
...
...
@@ -708,85 +839,19 @@ bool land()
return
flightTaskControl
.
response
.
result
;
}
std
::
vector
<
float
>
relativePosition
(
float
x
,
float
y
,
float
z
,
float
yaw
)
{
// convert relative position to velocity command
std
::
vector
<
float
>
posVec
{
x
,
y
,
z
};
// TESTING SMALL ANGLE ERROR IN PLACEMENT OF DRONE
// ------------------------------
// posVec = MatrixMultiply(rotateAxisAngle(std::vector<float> {0.0, 0.0, 1.0}, (M_PI/180.0)*180.0), posVec);
float
totalDist
=
Magnitude3
(
posVec
);
float
speed
;
float
totalTimeMs
;
// first check if we can make it in the allotted time
if
((
totalDist
/
controlLoopTime
)
>
maxSpeedParam
)
{
speed
=
maxSpeedParam
;
totalTimeMs
=
controlLoopTime
*
1000.0
;
}
else
{
speed
=
max
(
minSpeedParam
,
static_cast
<
double
>
(
totalDist
/
controlLoopTime
));
totalTimeMs
=
(
totalDist
/
speed
)
*
1000.0
;
// convert from s to ms, aim just short of position
}
std
::
vector
<
float
>
velDir
=
normalizeVector
(
posVec
);
std
::
vector
<
float
>
velVec
=
{
velDir
[
0
]
*
speed
,
velDir
[
1
]
*
speed
,
velDir
[
2
]
*
speed
};
dji_osdk_ros
::
FlightTaskControl
flightTaskControl
;
dji_osdk_ros
::
JoystickParams
joystickParams
;
joystickParams
.
x
=
velVec
[
0
];
joystickParams
.
y
=
velVec
[
1
];
joystickParams
.
z
=
velVec
[
2
];
if
(
abs
(
yaw
)
>=
0.05
)
{
float
tempYawRate
=
(
180.0
/
M_PI
)
*
yaw
/
(
totalTimeMs
/
1000.0
);
if
(
abs
(
tempYawRate
)
>
maxYawSpeedParam
)
{
tempYawRate
=
(
tempYawRate
/
abs
(
tempYawRate
))
*
maxYawSpeedParam
;
// if distance is small, let yaw dictate duration
// if (totalDist <= 0.1)
// {
// totalTimeMs = (abs(yaw)/tempYawRate)*1000.0;
// }
}
joystickParams
.
yaw
=
tempYawRate
;
}
else
{
joystickParams
.
yaw
=
0.0
;
}
ROS_INFO
(
"yaw rate: %f, speed: %f, over %f sec, going %fm"
,
joystickParams
.
yaw
,
speed
,
(
totalTimeMs
/
1000.0
),
totalDist
);
ROS_INFO
(
"---------------
\n
"
);
flightTaskControl
.
request
.
task
=
dji_osdk_ros
::
FlightTaskControl
::
Request
::
TASK_VELOCITY_AND_YAWRATE_CONTROL
;
flightTaskControl
.
request
.
joystickCommand
=
joystickParams
;
flightTaskControl
.
request
.
velocityControlTimeMs
=
totalTimeMs
;
flightTaskControl
.
request
.
posThresholdInM
=
0.1
;
flightTaskControl
.
request
.
yawThresholdInDeg
=
1
;
flight_control_client
.
call
(
flightTaskControl
);
// actually waits for drone to "reach" position
// return flightTaskControl.response.result;
return
std
::
vector
<
float
>
{(
totalTimeMs
/
1000.0
)
*
velVec
[
0
],
(
totalTimeMs
/
1000.0
)
*
velVec
[
1
],
(
totalTimeMs
/
1000.0
)
*
velVec
[
2
]};
}
bool
stopMotion
()
{
if
(
waypoint
MissionFlag
)
if
(
gps
MissionFlag
)
{
dji_osdk_ros
::
MissionWpAction
waypointAction
;
waypointAction
.
request
.
action
=
dji_osdk_ros
::
MissionWpAction
::
Request
::
ACTION_STOP
;
// stahhp
waypoint_action_client
.
call
(
waypointAction
);
waypoint
MissionFlag
=
false
;
gps
MissionFlag
=
false
;
}
if
(
position
MissionFlag
)
if
(
local
MissionFlag
)
{
position
MissionFlag
=
false
;
local
MissionFlag
=
false
;
}
return
true
;
}
...
...
@@ -800,21 +865,6 @@ bool goHome()
return
flightTaskControl
.
response
.
result
;
}
// void updateMagnitudeScaler(float newValue)
// {
// // remove the last value and insert new one
// calibrationWindowValues.pop_back();
// auto firstIndex = calibrationWindowValues.begin();
// calibrationWindowValues.insert(firstIndex, newValue);
// float sumer = 0.0;
// for (int i = 0; i < calibrationWindowValues.size(); i++)
// {
// sumer += calibrationWindowValues[i];
// }
// poseMagnitudeScaler = sumer/calibrationWindowValues.size();
// }
void
updateAngleScaler
(
float
newValue
)
{
// remove the last value and insert new one
...
...
@@ -826,42 +876,115 @@ void updateAngleScaler(float newValue)
{
sumer
+=
calibrationWindowValues
[
i
];
}
// check for first iteration, everything else is zero
// if (sumer == newValue)
// {
// // fill up with first value??
// for (int i = 0; i < calibrationWindowValues.size(); i++)
// {
// calibrationWindowValues[i] = newValue;
// }
// }
angleOffset
=
sumer
/
calibrationWindowValues
.
size
();
// angleOffset = calibrationWindowValues[firstIndex]; // just take most recent
}
void
calibratePositionReference
(
std
::
vector
<
float
>
requestedPosition
,
std
::
vector
<
float
>
actualPosition
)
// WIP
void
calibratePositionReference
()
{
// calculate rotation matrix
poseRotationMatrix
=
rotateAlign
(
requestedPosition
,
actualPosition
);
std
::
vector
<
float
>
deltaPosition
=
{
1.0
,
0.0
,
0.0
};
std
::
vector
<
float
>
startPosition
{
static_cast
<
float
>
(
ex_pos
.
translation
.
x
),
static_cast
<
float
>
(
ex_pos
.
translation
.
y
),
static_cast
<
float
>
(
ex_pos
.
translation
.
z
)
};
// go forward at 1m/s for 1s
relativeVelocity
(
deltaPosition
[
0
],
deltaPosition
[
1
],
deltaPosition
[
2
],
0.0
,
1.0
);
ros
::
Rate
(
1
).
sleep
();
ros
::
spinOnce
();
// let topics update
std
::
vector
<
float
>
deltaPositionActual
{
static_cast
<
float
>
(
ex_pos
.
translation
.
x
)
-
startPosition
[
0
],
static_cast
<
float
>
(
ex_pos
.
translation
.
y
)
-
startPosition
[
1
],
static_cast
<
float
>
(
ex_pos
.
translation
.
z
)
-
startPosition
[
2
]
};
relativeVelocity
(
-
deltaPosition
[
0
],
-
deltaPosition
[
1
],
-
deltaPosition
[
2
],
0.0
,
1.0
);
ros
::
Rate
(
1
).
sleep
();
ros
::
spinOnce
();
// recalculate the rotation offset
// check expected velocity verses actual velocity
ROS_INFO
(
"calibrating angle offset"
);
if
(
Magnitude3
(
deltaPosition
)
!=
0.0
&&
Magnitude3
(
deltaPositionActual
)
!=
0.0
)
{
float
ang
=
-
flatAngleBetween
(
deltaPositionActual
,
deltaPosition
);
ROS_INFO
(
"new angle offset: %f"
,
ang
);
angleOffsetParam
=
static_cast
<
double
>
(
ang
);
// updateAngleScaler(ang);
}
// now get scaling difference between coordinate frames
float
requestedPositionMag
=
Magnitude3
(
requestedPosition
);
float
actualPositionMag
=
Magnitude3
(
actualPosition
);
}
poseMagnitudeScaler
=
(
requestedPositionMag
/
actualPositionMag
);
void
pdMaxSpeedCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
)
{
// update MaxSpeed parameters
maxSpeedParam
=
msg
->
data
;
return
;
}
calibrationWindowValues
=
std
::
vector
<
float
>
{};
poseRotationMatrixValues
=
std
::
vector
<
std
::
vector
<
std
::
vector
<
float
>>>
{{{}}};
for
(
int
i
=
0
;
i
<
calibrationWindow
;
i
++
)
void
pdMaxYawSpeedCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
)
{
// update MaxYawSpeed parameters
maxYawSpeedParam
=
msg
->
data
;
return
;
}
void
pdSpeedScaleCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
)
{
// update SpeedScale parameters
speedScalarParam
=
msg
->
data
;
return
;
}
void
pdDampingCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
)
{
// update SpeedScale parameters
if
(
msg
->
data
<
0.0
)
{
calibrationWindowValues
.
push_back
(
poseMagnitudeScaler
);
poseRotationMatrixValues
.
push_back
(
poseRotationMatrix
);
return
;
}
damping
=
static_cast
<
double
>
(
msg
->
data
);
kp
=
(
6.0
*
frequency
)
*
(
6.0
*
frequency
)
*
0.25
;
kd
=
4.5
*
frequency
*
damping
;
return
;
}
ROS_INFO
(
"pose magnitude scalar %f"
,
poseMagnitudeScaler
);
void
pdFrequencyCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
)
{
// update SpeedScale parameters
if
(
msg
->
data
<
0.0
)
{
return
;
}
frequency
=
static_cast
<
double
>
(
msg
->
data
);
kp
=
(
6.0
*
frequency
)
*
(
6.0
*
frequency
)
*
0.25
;
kd
=
4.5
*
frequency
*
damping
;
return
;
}
void
pdAngleOffsetCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
)
{
// update SpeedScale parameters
angleOffsetParam
=
msg
->
data
;
return
;
}
// bool add(beginner_tutorials::AddTwoInts::Request &req, beginner_tutorials::AddTwoInts::Response &res)
void
pdUpdateRateCallback
(
const
std_msgs
::
Float32
::
ConstPtr
&
msg
)
{
// update UpdateRate parameters
if
(
msg
->
data
==
0.0
)
{
return
;
}
updateRateParam
=
msg
->
data
;
controlLoopTime
=
1.0
/
updateRateParam
;
return
;
}
bool
overwatchFunction
(
dji_osdk_ros
::
Overwatch
::
Request
&
req
,
dji_osdk_ros
::
Overwatch
::
Response
&
res
)
{
...
...
@@ -916,15 +1039,12 @@ bool overwatchFunction(dji_osdk_ros::Overwatch::Request &req, dji_osdk_ros::Over
takeoff
();
break
;
}
// case 7:
// {
// ROS_INFO("received overwatch: calibrate pos ref");
//
// std::vector<float> requestedPosition = {0.5, 0.0, 0.0};
// std::vector<float> actualPosition = DoCalibrationMove(requestedPosition);
// calibratePositionReference(requestedPosition, actualPosition);
// break;
// }
case
7
:
{
ROS_INFO
(
"received overwatch: calibrate pos ref"
);
calibratePositionReference
();
break
;
}
default
:
break
;
}
...
...
@@ -939,13 +1059,14 @@ int main(int argc, char** argv)
ros
::
init
(
argc
,
argv
,
"mission_node"
);
ros
::
NodeHandle
nh
;
ros
::
param
::
get
(
"base_speed"
,
baseSpeedParam
);
ros
::
param
::
get
(
"min_speed"
,
minSpeedParam
);
ros
::
param
::
get
(
"base_speed"
,
waypointSpeedParam
);
ros
::
param
::
get
(
"max_speed"
,
maxSpeedParam
);
ros
::
param
::
get
(
"max_yaw_speed"
,
maxYawSpeedParam
);
ros
::
param
::
get
(
"angle_offset"
,
angleOffsetParam
);
ros
::
param
::
get
(
"speed_scalar"
,
speedScalarParam
);
ros
::
param
::
get
(
"drone_id"
,
droneId
);
ros
::
param
::
get
(
"position_playback"
,
positionPlaybackParam
);
ros
::
param
::
get
(
"mission_type"
,
missionTypeParam
);
ros
::
param
::
get
(
"position_threshold"
,
positionThresholdParam
);
ros
::
param
::
get
(
"loop_rate"
,
updateRateParam
);
controlLoopTime
=
1.0
/
updateRateParam
;
// additions
...
...
@@ -960,29 +1081,38 @@ int main(int argc, char** argv)
{
calibrationWindowValues
.
push_back
(
0.0
);
}
// kp = (18.0*frequency*frequency)/2.0;
// kd = (9.0/2.0)*frequency*damping;
previousWallTime
=
ros
::
WallTime
::
now
();
// set puredata position to zero zero so it doesn't immediately fly away
pd_pos
.
translation
.
x
=
0.0
;
pd_pos
.
translation
.
y
=
0.0
;
pd_pos
.
translation
.
z
=
1.5
;
pd_pos
.
rotation
.
x
=
0.0
;
// ROS stuff
// obtain control authority?
obtain_ctrl_authority_client
=
nh
.
serviceClient
<
dji_osdk_ros
::
ObtainControlAuthority
>
(
"obtain_release_control_authority"
);
waypoint_upload_client
=
nh
.
serviceClient
<
dji_osdk_ros
::
MissionWpUpload
>
(
"dji_osdk_ros/mission_waypoint_upload"
);
waypoint_action_client
=
nh
.
serviceClient
<
dji_osdk_ros
::
MissionWpAction
>
(
"dji_osdk_ros/mission_waypoint_action"
);
flight_control_client
=
nh
.
serviceClient
<
dji_osdk_ros
::
FlightTaskControl
>
(
"flight_task_control"
);
syncPub
=
nh
.
advertise
<
std_msgs
::
Float32
>
(
"sync_signal"
,
1
);
//
syncPub = nh.advertise<std_msgs::Float32>("sync_signal", 1);
gps_pos_subscriber
=
nh
.
subscribe
<
sensor_msgs
::
NavSatFix
>
(
"dji_osdk_ros/gps_position"
,
1
,
&
gpsPosCallback
);
pos_feedback_subscriber
=
nh
.
subscribe
<
geometry_msgs
::
Transform
>
(
"feedback"
,
1
,
&
posFeedbackCallback
);
pos_tracking_subscriber
=
nh
.
subscribe
<
geometry_msgs
::
Transform
>
(
"tracking"
,
1
,
&
posTrackingCallback
);
pd_position_subscriber
=
nh
.
subscribe
<
geometry_msgs
::
Transform
>
(
"pd/target"
,
1
,
&
pdPositionCallback
);
// pd_parameter_MinSpeed_subscriber = nh.subscribe<std_msgs::Float32>("pd/parameters/minSpeed", 1, &pdMinSpeedCallback);
pd_parameter_MaxSpeed_subscriber
=
nh
.
subscribe
<
std_msgs
::
Float32
>
(
"pd/parameters/maxSpeed"
,
1
,
&
pdMaxSpeedCallback
);
pd_parameter_MaxYawSpeed_subscriber
=
nh
.
subscribe
<
std_msgs
::
Float32
>
(
"pd/parameters/maxYawSpeed"
,
1
,
&
pdMaxYawSpeedCallback
);
pd_parameter_SpeedScale_subscriber
=
nh
.
subscribe
<
std_msgs
::
Float32
>
(
"pd/parameters/speedScale"
,
1
,
&
pdSpeedScaleCallback
);
pd_parameter_UpdateRate_subscriber
=
nh
.
subscribe
<
std_msgs
::
Float32
>
(
"pd/parameters/updateRate"
,
1
,
&
pdUpdateRateCallback
);
pd_parameter_AngleOffset_subscriber
=
nh
.
subscribe
<
std_msgs
::
Float32
>
(
"pd/parameters/angleOffset"
,
1
,
&
pdAngleOffsetCallback
);
pd_parameter_Damping_subscriber
=
nh
.
subscribe
<
std_msgs
::
Float32
>
(
"pd/parameters/controllerDamping"
,
1
,
&
pdDampingCallback
);
pd_parameter_Frequency_subscriber
=
nh
.
subscribe
<
std_msgs
::
Float32
>
(
"pd/parameters/controllerFrequency"
,
1
,
&
pdFrequencyCallback
);
ros
::
ServiceServer
overwatchService
=
nh
.
advertiseService
(
"overwatch"
,
overwatchFunction
);
...
...
misson_controller/CMakeLists.txt
0 → 100644
View file @
c2e326c8
cmake_minimum_required
(
VERSION 3.0.2
)
project
(
misson_controller
)
## Compile as C++11, supported in ROS Kinetic and newer
# add_compile_options(-std=c++11)
## Find catkin macros and libraries
## if COMPONENTS list like find_package(catkin REQUIRED COMPONENTS xyz)
## is used, also find other catkin packages
find_package
(
catkin REQUIRED COMPONENTS
geometry_msgs
roscpp
rospy
sensor_msgs
std_msgs
)
## System dependencies are found with CMake's conventions
# find_package(Boost REQUIRED COMPONENTS system)
## Uncomment this if the package has a setup.py. This macro ensures
## modules and global scripts declared therein get installed
## See http://ros.org/doc/api/catkin/html/user_guide/setup_dot_py.html
# catkin_python_setup()
################################################
## Declare ROS messages, services and actions ##
################################################
## To declare and build messages, services or actions from within this
## package, follow these steps:
## * Let MSG_DEP_SET be the set of packages whose message types you use in
## your messages/services/actions (e.g. std_msgs, actionlib_msgs, ...).
## * In the file package.xml:
## * add a build_depend tag for "message_generation"
## * add a build_depend and a exec_depend tag for each package in MSG_DEP_SET
## * If MSG_DEP_SET isn't empty the following dependency has been pulled in
## but can be declared for certainty nonetheless:
## * add a exec_depend tag for "message_runtime"
## * In this file (CMakeLists.txt):
## * add "message_generation" and every package in MSG_DEP_SET to
## find_package(catkin REQUIRED COMPONENTS ...)
## * add "message_runtime" and every package in MSG_DEP_SET to
## catkin_package(CATKIN_DEPENDS ...)
## * uncomment the add_*_files sections below as needed
## and list every .msg/.srv/.action file to be processed
## * uncomment the generate_messages entry below
## * add every package in MSG_DEP_SET to generate_messages(DEPENDENCIES ...)
## Generate messages in the 'msg' folder
# add_message_files(
# FILES
# Message1.msg
# Message2.msg
# )
## Generate services in the 'srv' folder
# add_service_files(
# FILES
# Service1.srv
# Service2.srv
# )
## Generate actions in the 'action' folder
# add_action_files(
# FILES
# Action1.action
# Action2.action
# )
## Generate added messages and services with any dependencies listed here
# generate_messages(
# DEPENDENCIES
# geometry_msgs# sensor_msgs# std_msgs
# )
################################################
## Declare ROS dynamic reconfigure parameters ##
################################################
## To declare and build dynamic reconfigure parameters within this
## package, follow these steps:
## * In the file package.xml:
## * add a build_depend and a exec_depend tag for "dynamic_reconfigure"
## * In this file (CMakeLists.txt):
## * add "dynamic_reconfigure" to
## find_package(catkin REQUIRED COMPONENTS ...)
## * uncomment the "generate_dynamic_reconfigure_options" section below
## and list every .cfg file to be processed
## Generate dynamic reconfigure parameters in the 'cfg' folder
# generate_dynamic_reconfigure_options(
# cfg/DynReconf1.cfg
# cfg/DynReconf2.cfg
# )
###################################
## catkin specific configuration ##
###################################
## The catkin_package macro generates cmake config files for your package
## Declare things to be passed to dependent projects
## INCLUDE_DIRS: uncomment this if your package contains header files
## LIBRARIES: libraries you create in this project that dependent projects also need
## CATKIN_DEPENDS: catkin_packages dependent projects also need
## DEPENDS: system dependencies of this project that dependent projects also need
catkin_package
(
# INCLUDE_DIRS include
# LIBRARIES misson_controller
# CATKIN_DEPENDS geometry_msgs roscpp rospy sensor_msgs std_msgs
# DEPENDS system_lib
)
###########
## Build ##
###########
## Specify additional locations of header files
## Your package locations should be listed before other locations
include_directories
(
# include
${
catkin_INCLUDE_DIRS
}
)
## Declare a C++ library
# add_library(${PROJECT_NAME}
# src/${PROJECT_NAME}/misson_controller.cpp
# )
## Add cmake target dependencies of the library
## as an example, code may need to be generated before libraries
## either from message generation or dynamic reconfigure
# add_dependencies(${PROJECT_NAME} ${${PROJECT_NAME}_EXPORTED_TARGETS} ${catkin_EXPORTED_TARGETS})
## Declare a C++ executable
## With catkin_make all packages are built within a single CMake context
## The recommended prefix ensures that target names across packages don't collide
# add_executable(${PROJECT_NAME}_node src/misson_controller_node.cpp)
## Rename C++ executable without prefix
## The above recommended prefix causes long target names, the following renames the
## target back to the shorter version for ease of user use
## e.g. "rosrun someones_pkg node" instead of "rosrun someones_pkg someones_pkg_node"
# set_target_properties(${PROJECT_NAME}_node PROPERTIES OUTPUT_NAME node PREFIX "")
## Add cmake target dependencies of the executable
## same as for the library above
# add_dependencies(${PROJECT_NAME}_node ${${PROJECT_NAME}_EXPORTED_TARGETS} ${catkin_EXPORTED_TARGETS})
## Specify libraries to link a library or executable target against
# target_link_libraries(${PROJECT_NAME}_node
# ${catkin_LIBRARIES}
# )
#############
## Install ##
#############
# all install targets should use catkin DESTINATION variables
# See http://ros.org/doc/api/catkin/html/adv_user_guide/variables.html
## Mark executable scripts (Python etc.) for installation
## in contrast to setup.py, you can choose the destination
# catkin_install_python(PROGRAMS
# scripts/my_python_script
# DESTINATION ${CATKIN_PACKAGE_BIN_DESTINATION}
# )
## Mark executables for installation
## See http://docs.ros.org/melodic/api/catkin/html/howto/format1/building_executables.html
# install(TARGETS ${PROJECT_NAME}_node
# RUNTIME DESTINATION ${CATKIN_PACKAGE_BIN_DESTINATION}
# )
## Mark libraries for installation
## See http://docs.ros.org/melodic/api/catkin/html/howto/format1/building_libraries.html
# install(TARGETS ${PROJECT_NAME}
# ARCHIVE DESTINATION ${CATKIN_PACKAGE_LIB_DESTINATION}
# LIBRARY DESTINATION ${CATKIN_PACKAGE_LIB_DESTINATION}
# RUNTIME DESTINATION ${CATKIN_GLOBAL_BIN_DESTINATION}
# )
## Mark cpp header files for installation
# install(DIRECTORY include/${PROJECT_NAME}/
# DESTINATION ${CATKIN_PACKAGE_INCLUDE_DESTINATION}
# FILES_MATCHING PATTERN "*.h"
# PATTERN ".svn" EXCLUDE
# )
## Mark other files for installation (e.g. launch and bag files, etc.)
# install(FILES
# # myfile1
# # myfile2
# DESTINATION ${CATKIN_PACKAGE_SHARE_DESTINATION}
# )
#############
## Testing ##
#############
## Add gtest based cpp test target and link libraries
# catkin_add_gtest(${PROJECT_NAME}-test test/test_misson_controller.cpp)
# if(TARGET ${PROJECT_NAME}-test)
# target_link_libraries(${PROJECT_NAME}-test ${PROJECT_NAME})
# endif()
## Add folders to be run by python nosetests
# catkin_add_nosetests(test)
misson_controller/package.xml
0 → 100644
View file @
c2e326c8
<?xml version="1.0"?>
<package
format=
"2"
>
<name>
misson_controller
</name>
<version>
0.0.0
</version>
<description>
The misson_controller package
</description>
<!-- One maintainer tag required, multiple allowed, one person per tag -->
<!-- Example: -->
<!-- <maintainer email="jane.doe@example.com">Jane Doe</maintainer> -->
<maintainer
email=
"hlarkin3@vt.edu"
>
larkin
</maintainer>
<!-- One license tag required, multiple allowed, one license per tag -->
<!-- Commonly used license strings: -->
<!-- BSD, MIT, Boost Software License, GPLv2, GPLv3, LGPLv2.1, LGPLv3 -->
<license>
TODO
</license>
<!-- Url tags are optional, but multiple are allowed, one per tag -->
<!-- Optional attribute type can be: website, bugtracker, or repository -->
<!-- Example: -->
<!-- <url type="website">http://wiki.ros.org/misson_controller</url> -->
<!-- Author tags are optional, multiple are allowed, one per tag -->
<!-- Authors do not have to be maintainers, but could be -->
<!-- Example: -->
<!-- <author email="jane.doe@example.com">Jane Doe</author> -->
<!-- The *depend tags are used to specify dependencies -->
<!-- Dependencies can be catkin packages or system dependencies -->
<!-- Examples: -->
<!-- Use depend as a shortcut for packages that are both build and exec dependencies -->
<!-- <depend>roscpp</depend> -->
<!-- Note that this is equivalent to the following: -->
<!-- <build_depend>roscpp</build_depend> -->
<!-- <exec_depend>roscpp</exec_depend> -->
<!-- Use build_depend for packages you need at compile time: -->
<!-- <build_depend>message_generation</build_depend> -->
<!-- Use build_export_depend for packages you need in order to build against this package: -->
<!-- <build_export_depend>message_generation</build_export_depend> -->
<!-- Use buildtool_depend for build tool packages: -->
<!-- <buildtool_depend>catkin</buildtool_depend> -->
<!-- Use exec_depend for packages you need at runtime: -->
<!-- <exec_depend>message_runtime</exec_depend> -->
<!-- Use test_depend for packages you need only for testing: -->
<!-- <test_depend>gtest</test_depend> -->
<!-- Use doc_depend for packages you need only for building documentation: -->
<!-- <doc_depend>doxygen</doc_depend> -->
<buildtool_depend>
catkin
</buildtool_depend>
<build_depend>
geometry_msgs
</build_depend>
<build_depend>
roscpp
</build_depend>
<build_depend>
rospy
</build_depend>
<build_depend>
sensor_msgs
</build_depend>
<build_depend>
std_msgs
</build_depend>
<build_export_depend>
geometry_msgs
</build_export_depend>
<build_export_depend>
roscpp
</build_export_depend>
<build_export_depend>
rospy
</build_export_depend>
<build_export_depend>
sensor_msgs
</build_export_depend>
<build_export_depend>
std_msgs
</build_export_depend>
<exec_depend>
geometry_msgs
</exec_depend>
<exec_depend>
roscpp
</exec_depend>
<exec_depend>
rospy
</exec_depend>
<exec_depend>
sensor_msgs
</exec_depend>
<exec_depend>
std_msgs
</exec_depend>
<!-- The export tag contains other, unspecified, tags -->
<export>
<!-- Other tools can request additional information be placed here -->
</export>
</package>
puredata/CMakeLists.txt
0 → 100644
View file @
c2e326c8
cmake_minimum_required
(
VERSION 3.0.2
)
project
(
puredata
)
## Compile as C++11, supported in ROS Kinetic and newer
# add_compile_options(-std=c++11)
## Find catkin macros and libraries
## if COMPONENTS list like find_package(catkin REQUIRED COMPONENTS xyz)
## is used, also find other catkin packages
find_package
(
catkin REQUIRED COMPONENTS
roscpp
rospy
std_msgs
geometry_msgs
)
## System dependencies are found with CMake's conventions
# find_package(Boost REQUIRED COMPONENTS system)
## Uncomment this if the package has a setup.py. This macro ensures
## modules and global scripts declared therein get installed
## See http://ros.org/doc/api/catkin/html/user_guide/setup_dot_py.html
# catkin_python_setup()
################################################
## Declare ROS messages, services and actions ##
################################################
## To declare and build messages, services or actions from within this
## package, follow these steps:
## * Let MSG_DEP_SET be the set of packages whose message types you use in
## your messages/services/actions (e.g. std_msgs, actionlib_msgs, ...).
## * In the file package.xml:
## * add a build_depend tag for "message_generation"
## * add a build_depend and a exec_depend tag for each package in MSG_DEP_SET
## * If MSG_DEP_SET isn't empty the following dependency has been pulled in
## but can be declared for certainty nonetheless:
## * add a exec_depend tag for "message_runtime"
## * In this file (CMakeLists.txt):
## * add "message_generation" and every package in MSG_DEP_SET to
## find_package(catkin REQUIRED COMPONENTS ...)
## * add "message_runtime" and every package in MSG_DEP_SET to
## catkin_package(CATKIN_DEPENDS ...)
## * uncomment the add_*_files sections below as needed
## and list every .msg/.srv/.action file to be processed
## * uncomment the generate_messages entry below
## * add every package in MSG_DEP_SET to generate_messages(DEPENDENCIES ...)
## Generate messages in the 'msg' folder
# add_message_files(
# FILES
# Message1.msg
# Message2.msg
# )
## Generate services in the 'srv' folder
# add_service_files(
# FILES
# Service1.srv
# Service2.srv
# )
## Generate actions in the 'action' folder
# add_action_files(
# FILES
# Action1.action
# Action2.action
# )
## Generate added messages and services with any dependencies listed here
# generate_messages(
# DEPENDENCIES
# std_msgs
# )
################################################
## Declare ROS dynamic reconfigure parameters ##
################################################
## To declare and build dynamic reconfigure parameters within this
## package, follow these steps:
## * In the file package.xml:
## * add a build_depend and a exec_depend tag for "dynamic_reconfigure"
## * In this file (CMakeLists.txt):
## * add "dynamic_reconfigure" to
## find_package(catkin REQUIRED COMPONENTS ...)
## * uncomment the "generate_dynamic_reconfigure_options" section below
## and list every .cfg file to be processed
## Generate dynamic reconfigure parameters in the 'cfg' folder
# generate_dynamic_reconfigure_options(
# cfg/DynReconf1.cfg
# cfg/DynReconf2.cfg
# )
###################################
## catkin specific configuration ##
###################################
## The catkin_package macro generates cmake config files for your package
## Declare things to be passed to dependent projects
## INCLUDE_DIRS: uncomment this if your package contains header files
## LIBRARIES: libraries you create in this project that dependent projects also need
## CATKIN_DEPENDS: catkin_packages dependent projects also need
## DEPENDS: system dependencies of this project that dependent projects also need
catkin_package
(
INCLUDE_DIRS include
LIBRARIES puredata
CATKIN_DEPENDS roscpp rospy std_msgs geometry_msgs
DEPENDS system_lib
)
###########
## Build ##
###########
## Specify additional locations of header files
## Your package locations should be listed before other locations
include_directories
(
# include
${
catkin_INCLUDE_DIRS
}
)
## Declare a C++ library
# add_library(${PROJECT_NAME}
# src/${PROJECT_NAME}/puredata.cpp
# )
## Add cmake target dependencies of the library
## as an example, code may need to be generated before libraries
## either from message generation or dynamic reconfigure
# add_dependencies(${PROJECT_NAME} ${${PROJECT_NAME}_EXPORTED_TARGETS} ${catkin_EXPORTED_TARGETS})
## Declare a C++ executable
## With catkin_make all packages are built within a single CMake context
## The recommended prefix ensures that target names across packages don't collide
# add_executable(${PROJECT_NAME}_node src/puredata_node.cpp)
## Rename C++ executable without prefix
## The above recommended prefix causes long target names, the following renames the
## target back to the shorter version for ease of user use
## e.g. "rosrun someones_pkg node" instead of "rosrun someones_pkg someones_pkg_node"
# set_target_properties(${PROJECT_NAME}_node PROPERTIES OUTPUT_NAME node PREFIX "")
## Add cmake target dependencies of the executable
## same as for the library above
# add_dependencies(${PROJECT_NAME}_node ${${PROJECT_NAME}_EXPORTED_TARGETS} ${catkin_EXPORTED_TARGETS})
## Specify libraries to link a library or executable target against
# target_link_libraries(${PROJECT_NAME}_node
# ${catkin_LIBRARIES}
# )
#############
## Install ##
#############
# all install targets should use catkin DESTINATION variables
# See http://ros.org/doc/api/catkin/html/adv_user_guide/variables.html
## Mark executable scripts (Python etc.) for installation
## in contrast to setup.py, you can choose the destination
# catkin_install_python(PROGRAMS
# scripts/my_python_script
# DESTINATION ${CATKIN_PACKAGE_BIN_DESTINATION}
# )
## Mark executables for installation
## See http://docs.ros.org/melodic/api/catkin/html/howto/format1/building_executables.html
# install(TARGETS ${PROJECT_NAME}_node
# RUNTIME DESTINATION ${CATKIN_PACKAGE_BIN_DESTINATION}
# )
## Mark libraries for installation
## See http://docs.ros.org/melodic/api/catkin/html/howto/format1/building_libraries.html
# install(TARGETS ${PROJECT_NAME}
# ARCHIVE DESTINATION ${CATKIN_PACKAGE_LIB_DESTINATION}
# LIBRARY DESTINATION ${CATKIN_PACKAGE_LIB_DESTINATION}
# RUNTIME DESTINATION ${CATKIN_GLOBAL_BIN_DESTINATION}
# )
## Mark cpp header files for installation
# install(DIRECTORY include/${PROJECT_NAME}/
# DESTINATION ${CATKIN_PACKAGE_INCLUDE_DESTINATION}
# FILES_MATCHING PATTERN "*.h"
# PATTERN ".svn" EXCLUDE
# )
## Mark other files for installation (e.g. launch and bag files, etc.)
# install(FILES
# # myfile1
# # myfile2
# DESTINATION ${CATKIN_PACKAGE_SHARE_DESTINATION}
# )
#############
## Testing ##
#############
## Add gtest based cpp test target and link libraries
# catkin_add_gtest(${PROJECT_NAME}-test test/test_puredata.cpp)
# if(TARGET ${PROJECT_NAME}-test)
# target_link_libraries(${PROJECT_NAME}-test ${PROJECT_NAME})
# endif()
## Add folders to be run by python nosetests
# catkin_add_nosetests(test)
puredata/package.xml
0 → 100644
View file @
c2e326c8
<?xml version="1.0"?>
<package
format=
"2"
>
<name>
puredata
</name>
<version>
0.0.0
</version>
<description>
The puredata package
</description>
<!-- One maintainer tag required, multiple allowed, one person per tag -->
<!-- Example: -->
<!-- <maintainer email="jane.doe@example.com">Jane Doe</maintainer> -->
<maintainer
email=
"hlarkin3@vt.edu"
>
larkin
</maintainer>
<!-- One license tag required, multiple allowed, one license per tag -->
<!-- Commonly used license strings: -->
<!-- BSD, MIT, Boost Software License, GPLv2, GPLv3, LGPLv2.1, LGPLv3 -->
<license>
TODO
</license>
<!-- Url tags are optional, but multiple are allowed, one per tag -->
<!-- Optional attribute type can be: website, bugtracker, or repository -->
<!-- Example: -->
<!-- <url type="website">http://wiki.ros.org/puredata</url> -->
<!-- Author tags are optional, multiple are allowed, one per tag -->
<!-- Authors do not have to be maintainers, but could be -->
<!-- Example: -->
<!-- <author email="jane.doe@example.com">Jane Doe</author> -->
<!-- The *depend tags are used to specify dependencies -->
<!-- Dependencies can be catkin packages or system dependencies -->
<!-- Examples: -->
<!-- Use depend as a shortcut for packages that are both build and exec dependencies -->
<!-- <depend>roscpp</depend> -->
<!-- Note that this is equivalent to the following: -->
<!-- <build_depend>roscpp</build_depend> -->
<!-- <exec_depend>roscpp</exec_depend> -->
<!-- Use build_depend for packages you need at compile time: -->
<!-- <build_depend>message_generation</build_depend> -->
<!-- Use build_export_depend for packages you need in order to build against this package: -->
<!-- <build_export_depend>message_generation</build_export_depend> -->
<!-- Use buildtool_depend for build tool packages: -->
<!-- <buildtool_depend>catkin</buildtool_depend> -->
<!-- Use exec_depend for packages you need at runtime: -->
<!-- <exec_depend>message_runtime</exec_depend> -->
<!-- Use test_depend for packages you need only for testing: -->
<!-- <test_depend>gtest</test_depend> -->
<!-- Use doc_depend for packages you need only for building documentation: -->
<!-- <doc_depend>doxygen</doc_depend> -->
<buildtool_depend>
catkin
</buildtool_depend>
<build_depend>
roscpp
</build_depend>
<build_depend>
rospy
</build_depend>
<build_depend>
std_msgs
</build_depend>
<build_depend>
geometry_msgs
</build_depend>
<build_export_depend>
roscpp
</build_export_depend>
<build_export_depend>
rospy
</build_export_depend>
<build_export_depend>
std_msgs
</build_export_depend>
<build_export_depend>
geometry_msgs
</build_export_depend>
<exec_depend>
roscpp
</exec_depend>
<exec_depend>
rospy
</exec_depend>
<exec_depend>
std_msgs
</exec_depend>
<exec_depend>
geometry_msgs
</exec_depend>
<!-- The export tag contains other, unspecified, tags -->
<export>
<!-- Other tools can request additional information be placed here -->
</export>
</package>
puredata/patches/crushedPiano.wav
0 → 100644
View file @
c2e326c8
File added
puredata/patches/drone-osc.pd
0 → 100644
View file @
c2e326c8
#N canvas 0 96 1013 984 10;
#X obj 54 73 netreceive -u -b;
#X obj 55 98 oscparse;
#X obj 210 23 loadbang;
#X obj 210 56 del 100;
#X obj 55 123 route list;
#X obj 55 159 route sound;
#X obj 121 461 dac~ 1 2;
#X msg 42 279 start;
#X obj 55 211 select 1 0;
#X obj 54 252 t b b;
#X msg 110 273 stop;
#X obj 55 185 route one;
#X obj 121 428 *~;
#X obj 170 427 *~;
#X obj 227 154 route master;
#X obj 215 264 line~;
#X msg 227 182 \$1 100;
#X msg 210 83 \; pd dsp 1;
#X obj 16 202 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144 -1
-1;
#X obj 187 21 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144 -1
-1;
#X obj 95 356 readsf~ 2;
#X obj 175 392 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144
-1 -1;
#X obj 132 160 print oscin;
#X obj 343 387 readsf~ 2;
#X obj 345 429 dac~;
#X obj 317 277 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144
-1 -1;
#X msg 305 356 start;
#X msg 358 362 stop;
#X obj 304 337 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144
-1 -1;
#X obj 355 342 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144
-1 -1;
#X msg 54 49 listen 3722;
#X text 305 261 random testing stuff;
#X floatatom 280 182 5 0 0 0 - - -;
#X obj 53 6 loadbang;
#X text 34 334 need to pick different sounds here;
#X msg 340 305 open ./crushedPiano.wav;
#X obj 54 26 del 500;
#X msg 91 309 open ~/offlinePayload1/payload2-full.aif;
#X connect 0 0 1 0;
#X connect 1 0 4 0;
#X connect 2 0 3 0;
#X connect 3 0 17 0;
#X connect 4 0 5 0;
#X connect 4 0 14 0;
#X connect 4 0 22 0;
#X connect 5 0 11 0;
#X connect 7 0 20 0;
#X connect 8 0 9 0;
#X connect 8 1 10 0;
#X connect 9 0 7 0;
#X connect 9 1 37 0;
#X connect 10 0 20 0;
#X connect 11 0 8 0;
#X connect 12 0 6 0;
#X connect 13 0 6 1;
#X connect 14 0 16 0;
#X connect 14 0 32 0;
#X connect 15 0 12 1;
#X connect 15 0 13 1;
#X connect 16 0 15 0;
#X connect 18 0 9 0;
#X connect 19 0 3 0;
#X connect 20 0 12 0;
#X connect 20 1 13 0;
#X connect 20 2 21 0;
#X connect 23 0 24 0;
#X connect 23 1 24 1;
#X connect 25 0 35 0;
#X connect 26 0 23 0;
#X connect 27 0 23 0;
#X connect 28 0 26 0;
#X connect 29 0 27 0;
#X connect 30 0 0 0;
#X connect 33 0 36 0;
#X connect 35 0 23 0;
#X connect 36 0 30 0;
#X connect 37 0 20 0;
puredata/scripts/puredataLaunch.bash
0 → 100755
View file @
c2e326c8
#!/bin/bash
# need to figure out what these audio numbers should be!!
puredata
-r
48000
-nogui
-audiooutdev
5
-audioindev
5 ../patches/drone-osc.pd
puredata/scripts/puredataPublisher.py
0 → 100755
View file @
c2e326c8
#! /usr/bin/python3
import
rospy
import
sys
# from osc4py3.as_eventloop import *
# from osc4py3.as_allthreads import *
from
osc4py3.as_comthreads
import
*
from
osc4py3
import
oscmethod
as
osm
from
geometry_msgs.msg
import
Transform
from
std_msgs.msg
import
Float32
import
netifaces
as
ni
# blah blah blah
# AHHHHHHHHHHHHHHHHHHHHHHHHHHHHHHHHHHH
class
OSCTranslator
():
def
__init__
(
self
):
self
.
positionPub
=
rospy
.
Publisher
(
'pd/target'
,
Transform
,
queue_size
=
1
)
self
.
paramMaxSpeedPub
=
rospy
.
Publisher
(
'pd/parameters/maxSpeed'
,
Float32
,
queue_size
=
1
)
self
.
paramMaxYawSpeedPub
=
rospy
.
Publisher
(
'pd/parameters/maxYawSpeed'
,
Float32
,
queue_size
=
1
)
self
.
paramSpeedScalePub
=
rospy
.
Publisher
(
'pd/parameters/speedScale'
,
Float32
,
queue_size
=
1
)
self
.
paramUpdateRatePub
=
rospy
.
Publisher
(
'pd/parameters/updateRate'
,
Float32
,
queue_size
=
1
)
self
.
paramDampingPub
=
rospy
.
Publisher
(
'pd/parameters/damping'
,
Float32
,
queue_size
=
1
)
self
.
paramFrequencyPub
=
rospy
.
Publisher
(
'pd/parameters/frequency'
,
Float32
,
queue_size
=
1
)
self
.
paramAngleOffsetPub
=
rospy
.
Publisher
(
'pd/parameters/angleOffset'
,
Float32
,
queue_size
=
1
)
rospy
.
init_node
(
'puredata_publisher'
)
self
.
rate
=
rospy
.
Rate
(
100
)
self
.
target
=
Transform
()
rospy
.
loginfo
(
"starting osc server"
)
# Make server channels to receive packets.
# get wifi interfaces ip
# dont listen on the wireless when wanting it through the ethernet~
# osc_udp_server(ni.ifaddresses('wlan0')[ni.AF_INET][0]['addr'], 3721, "aservername")
osc_udp_server
(
ni
.
ifaddresses
(
'eth0'
)[
ni
.
AF_INET
][
0
][
'addr'
],
3721
,
"aservername"
)
osc_method
(
"/position"
,
self
.
handlerfunctionflex
,
argscheme
=
osm
.
OSCARG_ADDRESS
+
osm
.
OSCARG_DATAUNPACK
)
osc_method
(
"/parameters"
,
self
.
handlerfunctionflex
,
argscheme
=
osm
.
OSCARG_ADDRESS
+
osm
.
OSCARG_DATAUNPACK
)
osc_method
(
"/sound/one"
,
self
.
handlerfunctionflex
,
argscheme
=
osm
.
OSCARG_ADDRESS
+
osm
.
OSCARG_DATAUNPACK
)
osc_method
(
"/master"
,
self
.
handlerfunctionflex
,
argscheme
=
osm
.
OSCARG_ADDRESS
+
osm
.
OSCARG_DATAUNPACK
)
def
handlerfunctionflex
(
self
,
address
,
*
args
):
# Will receive message data unpacked in s, x, y
rospy
.
loginfo
(
"from: "
+
address
+
": "
+
str
(
args
))
if
(
address
==
"/position"
):
# rospy.loginfo("publishing position...")
self
.
target
.
translation
.
x
=
args
[
0
]
self
.
target
.
translation
.
y
=
args
[
1
]
self
.
target
.
translation
.
z
=
args
[
2
]
self
.
target
.
rotation
.
x
=
args
[
3
]
self
.
positionPub
.
publish
(
self
.
target
)
elif
(
address
==
"/parameters/maxSpeed"
):
# rospy.loginfo("new maxSpeed param: " + str(args[0]))
self
.
paramMaxSpeedPub
.
publish
(
args
[
0
])
elif
(
address
==
"/parameters/maxYawSpeed"
):
# rospy.loginfo("new maxYawSpeed param: " + str(args[0]))
self
.
paramMaxYawSpeedSpeedPub
.
publish
(
args
[
0
])
elif
(
address
==
"/parameters/speedScale"
):
# rospy.loginfo("new speedScale param: " + str(args[0]))
self
.
paramSpeedScalePub
.
publish
(
args
[
0
])
elif
(
address
==
"/parameters/updateRate"
):
# rospy.loginfo("new updateRate param: " + str(args[0]))
self
.
paramUpdateRatePub
.
publish
(
args
[
0
])
elif
(
address
==
"/parameters/damping"
):
# rospy.loginfo("new damping param: " + str(args[0]))
self
.
paramDampingPub
.
publish
(
args
[
0
])
elif
(
address
==
"/parameters/frequency"
):
# rospy.loginfo("new frequency param: " + str(args[0]))
self
.
paramFrequencyPub
.
publish
(
args
[
0
])
elif
(
address
==
"/parameters/angleOffset"
):
# rospy.loginfo("new angleOffset param: " + str(args[0]))
self
.
paramAngleOffsetPub
.
publish
(
args
[
0
])
elif
(
address
==
"/sound/one"
):
rospy
.
loginfo
(
"publishing sound..."
)
elif
(
address
==
"/master"
):
rospy
.
loginfo
(
"publishing master vol..."
)
# pure data will handle sounds..?
pass
if
__name__
==
"__main__"
:
osc_startup
()
oscer
=
OSCTranslator
()
rospy
.
loginfo
(
"starting osc process loop"
)
while
not
rospy
.
is_shutdown
():
# rospy.loginfo("processing osc msgs...")
osc_process
()
oscer
.
rate
.
sleep
()
# rospy.spin()
osc_terminate
()
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