Seite - 51 - in Joint Austrian Computer Vision and Robotics Workshop 2020
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the box is done by asynchronously opening the box
such that the model logs spread randomly on the
floor. The floor area designed as log picking area
can be shielded during a box emptying process to
prevent the logs from spreading too wide in the
area. With the project goal of the crane being
able to autonomously store the logs in the box,
this automated emptying process enables an endless
cycle for automated training refining the AI based
procedureswithout supervision.
The crane is controlled at a high level by an
external PC which is connected via Ethernet to
a HAWE-ESX control unit. The ESX controls
the hydraulic pistons and sends the signals of the
wire-rope and custom angular sensors via Ethernet
back to the host PC. The PC also receives data from
two cameras mounted on the fix and movable part
of the crane as well as from five IMUs mounted on
each of the crane joints. These sensors will serve
for automated model creation as we assume to not
have CAD drawings of every crane in a retrofitting
process. Theoverallconnectivityschematic isshown
inFig.3.
Figure 2. Crane model system with automated elements
for continuous learningwithout human intervention.
Figure 3. Overview on the connectivity of the model
crane, the sensors, and the externalPC. 2.1.RetrofittableSensors
Automating machinery in the wood sector is
challenging since not only the sensors that enable
autonomy need to be equipped ideally without
disassembling the machine, they also need to be
autarkic in terms of energy, and withstand very
harsh environments. Thus, robust magnetic angular
positionsensorsfollowing[1]suitablefor retrofitting
and wireless operation have been integrated on the
cranemodel. Theycaneasilybeadaptedfordifferent
joint geometries. The basic architecture is shown
in Fig. 4 together with the lab setup (currently
with wired CAN). In addition, capacitive sensors
Figure4.TheexperimentalsensorandCADcoilgeometry
on the rotary joint of the end-effector: The coil PCB and
signal processing circuitry is mounted to the non-rotating
head whereas the conductive plate is mounted on the
rotating shaft. The conductive counterpart consists of a
3Dprintedholder andwrappedcopper foil.
following [2] are integrated in the end-effector to
augment themachinerywithasense for loggrasping
quality (Fig.5). Thecraneandsensorsare simulated
Figure 5. Left: V-REP model. Bottom right: gripper
design. Top right: photograph of the gripper prototype
including the sensorelementswireless electronics.
in V-REP. There, the communication and control are
tested using V-REP/ROS and V-REP/Python bridge.
The simulation also serves as an environment for AI
training of the crane controls and for optimizations
on sensor placement following [3]. A video of the
simulation frameworkcanbe found in [4]
51
Joint Austrian Computer Vision and Robotics Workshop 2020
- Titel
- Joint Austrian Computer Vision and Robotics Workshop 2020
- Herausgeber
- Graz University of Technology
- Ort
- Graz
- Datum
- 2020
- Sprache
- englisch
- Lizenz
- CC BY 4.0
- ISBN
- 978-3-85125-752-6
- Abmessungen
- 21.0 x 29.7 cm
- Seiten
- 188
- Kategorien
- Informatik
- Technik