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manipulation planning framework presented in [3], [9], [16], [5], and [1] considered the trajectory
planning problem from the normal operation of a manipulation task. A time-series classification
algorithm was presented in [3] to perform the online prediction of human reaching motion by
applying a motion capture camera system. Partial segments of actual motion variables are
compared with the subset of motion variables which represent the optimally time aligned human
motion demonstrations. In [9], the predicted motion trajectories are represented as 3D voxels which
infers the workspace occupancy information. Similar approaches were adopted in [16], [5] for
human motion prediction. In [6], human-object interactions in combination with human motion
trajectories were used to build temporal conditional random fields for anticipating human activities.
In [1], a human worker’s intent was estimated by computing the probabilistic representation of
workspace segmented areas to which the human is heading.
Task and motion planners were integrated in [13] and [4] to identify and handle low-level process
deviations such as collision-prone trajectories with the neighbouring objects. Here, the process
addressed is a pick and place operation performed by a robot on a cluttered table and a payload
carried by two robots respectively. During the process execution, the interface layer in between the
task and motion planners determines the presence/absence of obstructions by identifying the
collision-prone trajectories from the trajectory planner as low-level process deviations. Based on
these deviations, the task planner is updated with a new state and sends a variation of the initial task
plan to the trajectory planner. An alternative way to handle these kinds of deviations is to replace
object grasping with multiple push-grasps in a cluttered environment [10]. With our work we intend
to enhance the state of the art by cascading activity recognition and task recognition to identify low-
level process deviations and perform task level trajectory planning. In this work, we also intend to
realize activity recognition by estimating the skeletal joint positions with a higher sampling rate.
1.2. Paper Organization
Section 2 deals with the methodology proposed for trajectory planning based on activity recognition
and identification of low-level process deviations. Section 3 will present the experimental setup
including a static process plan where the human worker and robot performs process steps/tasks
within their shared workspace. Section 4 will detail the expected contributions.
2. Methodology
In this section, the methodology behind the trajectory planning based on activity recognition and
identification of low-level process deviations will be described along with the system architecture.
Figure 2 depicts the system architecture which consists of 7 major building blocks 1) Object
tracking 2) Skeletal joints estimation 3) Action recognition 4) Activity recognition 5) Task
recognition 6) Trajectory planner and 7) High-level planner. The algorithms applied for object
tracking and action recognition components have already been realized and evaluated in [14] and
[15] respectively and will not be mentioned in this research work. Therefore, the methods required
for the remaining major blocks will be mentioned here.
202
Proceedings
OAGM & ARW Joint Workshop 2016 on "Computer Vision and Robotics“
- Titel
- Proceedings
- Untertitel
- OAGM & ARW Joint Workshop 2016 on "Computer Vision and Robotics“
- Autoren
- Peter M. Roth
- Kurt Niel
- Verlag
- Verlag der Technischen Universität Graz
- Ort
- Wels
- Datum
- 2017
- Sprache
- englisch
- Lizenz
- CC BY 4.0
- ISBN
- 978-3-85125-527-0
- Abmessungen
- 21.0 x 29.7 cm
- Seiten
- 248
- Schlagwörter
- Tagungsband
- Kategorien
- International
- Tagungsbände