Ulmsserver
Introduction
The laser scanner server (ulmsserver) has a number of statically linked modules for operation as a laser scanner server. It should be used primarily for plug-ins that are related to laser scanner data, but is able to handle any plugin (except some specific camera aware plugins that need the camera server environment).
Configurations
Typical configuration could be:
ulmsserver.ini for the SMR
server datapath="/vhome/jca/logfiles" server port=24919 # for laser devices module load='laserpool' # handling of (server-global) configuration values module load='var' # load coordinate system plug-in module load=odoPose # make logfile for odometry updates (odoPose.log in datapath) odopose log # Configure laser scanner devices scanset devtype='urg' devname="/dev/ttyACM0" scanset def=urg scanset x=0.22 y=0.0 z=0.05 scanset width=180 scanset logOpen scanset log=1
This loads the needed modules for laserscanner and odometry support Logfiles are placed in the path specified by datapath
The data from the URG laserscanner is saved in a logfile (the last 2 lines). The filename will be laser_0.log.
On top of this some modules to use the laserscans e.g. a localizer and obstacle generation:
module load=v360 module load=mapPose var mappose.estimateVel=true # obstacle handling (groups fixed and dynamic obst) module load="ulmspassable.so.0" # configure obstacle handling var pass.minObstDist = 0.05; var obst.outdoormode=0 var obst.obstGrpMaxDistance=0.025 var obst.obstGrpMaxTime=0.01 var obst.obstmerge=false var obst.obstCogMerge=true var obst.cogMergeLimit=2.0 var obst.singleMerge=true var obst.singleLimit = 0.03 # # display polygons m.v. module load="aupoly.so.0" # mapped lines etc. module load="mapbase.so.0" # # load module to utilize mapped obstacles module load="aumapobst.so.0" var mapobst.marginSolidFactor=0.3 var mapobst.marginFluffyFactor = 1.1 var mapobst.front=7 # # laser based dynamic obstacles module load="aulobst.so.0" var lobst.minSplitCnt=2 ; splitDist defines minimum opening var lobst.splitDist=0.15 var lobst.maxLineIterations=25 var lobst.maxSamples=80 var lobst.noobst="0.33 0.17 -0.2 -0.17 var lobst.lineeatdist=0.03 var lobst.maxtolinedist=0.04 # # localize based on lines and laserdata module load="aulocalize.so.0" setInitCov cx=0.09 cy=0.09 cth=0.09 setInitPose x=13.0 y=6.1 th=-1.57 var localize.wheelBase=0.46 var localize.sdmRight=0.11 var localize.sdmLeft=0.11 #; # processing of laserdata - into 360 degree scanner generation scanpush i=1 cmd="v360 update" # make obstacles 360 deg v360push i=2 cmd="lobst make obst silent" # localize about once a second v360push i=10 cmd="localize silent=1" # update fixed obstacles regularly push t=3 n=10 cmd="obst getfrommap makeonly" # load map lines into localizer # mapobst map2localize - moved to bygn326.rule
ulmsserver.ini for HAKO tractor
server datapath="/rhome/demo/log_laser" server serverlog # module load='laserpool' module load='var' module load='imagepool' module load='v360' module load=odoPose module load=utmPose module load=mapPose var mappose.estimateVel=true mapPose log # scanset devtype='sick' devname="/dev/ttyUSB0" scanset def=sick scanset res=0.5 # set scanner position in robot coordinates scanset x=2.07 y=0.0 z=0.52 scanset mirror=false scanset logOpen scanset log=4
plus a number of functional plugins and settings (from 6 oct 2010)
# interface to nav server (for odometry and utmpose) module load=if alias=nav nav add=var navOnConnect cmd="nav odoPosePush flush" navOnConnect cmd="nav odoPosePush cmd='odopose pose'" navOnConnect cmd="nav utmPosePush flush" navOnConnect cmd="nav utmPosePush cmd='utmpose pose'" nav connect=localhost:24922 ; module load="./ulmspassable.so.0" var obst.outdoormode=false var obst.obstGrpMaxDistance=0.025 var obst.obstGrpMaxTime=0.01 var obst.obstmerge=false var obst.obstCogMerge=false var obst.cogMergeLimit=2.0 var obst.singleMerge=true var obst.singleLimit = 0.03 ;scanpush i=3 cmd="pass obstonly makeonly" ; module load="./aupoly.so.0" module load="./aurule.so.0" rule step=0 rule load="./mapPose.rule" rule load="./building97.rule" rule load="./buildingChimney.rule" rule load="./buildingFuel.rule" rule load="./buildingHans.rule" rule load="./buildingGreenhouseSouth.rule" rule load="./buildingSouthSmall.rule" rule load="./agrovejEastFence.rule" rule load="./alleNorth.rule" rule load="./alleSouth.rule" # module load="./mapbase.so.0" #mapbase mapload="./apple_cherry_map.xml" mapbase graphload="./apple_cherry_graph.xml" mapbase mapload="./apple_cherry_map.xml" # load module to utilize mapped obstacles module load="./aumapobst.so.0" var mapobst.marginSolidFactor=0.3 var mapobst.marginFluffyFactor=1.4 # and locater relative to mapped lines module load="./locater.so.0" var locater.useRowEnd = 1 var locater.rowEndIn1 = 5.0 var locater.rowEndIn2 = 2.5 var locater.keepMapPose = 1.0 var locater.rowEndMaxGap=3.3 var locater.useAvgUpdate=1 var locater.rowToRobotMaxDist = 4.0 var locater.rowEndMaxDist=10.0 var locater.odoDistScale=1.0 locater openlog var call="locater.resetstate()" #scanpush cmd="locater locate" scanpush device=sick i=4 cmd="v360 update" ;v360push cmd="locater locate" ;v360push cmd="pass obstonly makeonly" ; ;utmposepush cmd="locater utmtomap" ;scanget rule log rule resume
Replay configuration
Laser scanner logfiles can be replayed, but a replay device must be added to the configuration file, e.g.
server datapath="/vhome/jca/logfiles" server replaypath="/vhome/jca/replay/laser1/log" <--- new line server port=24919 # for laser devices module load='laserpool' # handling of (server-global) configuration values module load='var' # load coordinate system plug-in module load=odoPose # make logfile for odometry updates (odoPose.log in datapath) # odopose log <--- changed to a comment odopose replay <--- new line # scanset devtype='urg' devname="/dev/ttyACM0" scanset def=urg scanset devtype='replay' devname="laser_0.log" <--- new device scanset def=replay <--- new line scanset x=0.22 y=0.0 z=0.05 scanset width=180 #scanset mirror=true <--- changed to comment #scanset logOpen <--- changed to comment #scanset log=1 <--- changed to comment ... # the rest of the configuration is unchanged - i.e. the functional modules that should be tested against the recorded laserscans.
This configuration should be saved in in a specific replay directory (here assumed to be ~/replay/laser1 In this directory make a subdirectory, e.g. called log
Place the logfiles in this directory.
cd ~/replay/laser1/ mkdir log cp ~/logfiles/*.log log/
Start the laser server
ulmsserver
And start stepping through the recorded laserscans:
>> scanset step <scanset tod="1266588146.403597" time="15:02:26.403" logLine="3"/> >>
If the auclient is running (and configured), then the scan should be visible in the navigation window.
The odometry pose can be stepped too:
>> odopose step <odopose tod="1266588154.579142" time="15:02:34.579" logLine="10"/> >>
Once opened the two datasets are synchronized using the timestamp in the logfiles.
Replay synchronized across servers
If a connection is established to e.g. the camera server, then this interface can be used to synchronize any replay on that server, an interface should then be included in the configuration file like:
# part of ulmsserver.ini module load=if alias=cam cam connect=localhost:24920 cam replay
And the other way if the image log-file is stepped, then an interface in the camera server must be established to the laser server, like:
# part of ucamserver.ini module load=if alias=laser laser connect=localhost:24919 laser replay
The the two servers should now stay synchronized regardless of which interface is stepped.
laser scan logfile
Filename for laser 0 is
laser_0.log
The file looks like this
1216815130.160302 25905 0.5 -90 361 5.789 5.782 5.806 5.776 7.619 7.810 7.931 5.803 5.793 ... 1216815130.213813 25907 0.5 -90 361 5.751 5.767 5.777 5.774 5.785 5.784 7.854 7.370 5.795 ... 1216815130.267325 25909 0.5 -90 361 7.628 8.130 5.770 5.780 5.755 5.787 5.802 5.793 7.828 ...
The fields are:
1 Timestamp (linux timestamp, valid to about 20ms) 2 scan number (e.g. 25909), 3 resolution (here 0.5 degree), 4 first angle (e.g. -90 degree), 5 number of measurements (e.g. 361), 6 first range (5.789 in meters), 7 second range (5.782) 8 ... and so forth.