New Approaches to Movement Evaluation Using Accurate Truck Ingress Data

Dorynek, Martin; Zhang, Hongtao; Hofmann, Norman; Bengler, Klaus

doi:10.1007/978-3-030-77817-0_10

Cited by 2 publications

(1 citation statement)

References 9 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the case of the truck, the height, width, and angle of the steps can be varied as can the door opening. The experiments for truck ingress have already been explained in Dorynek et al (2021). In the case of the car, the variations concerned the height of the sill and the roof.…”

Section: Methodsmentioning

confidence: 99%

On the progress of knowledge-based motion simulation techniques in ergonomic vehicle design

Wirsching

Hofmann²

2022

Proceedings of the 7th International Digital Human Modeling Symposium -

Self Cite

View full text Add to dashboard Cite

Applying DHMs in ergonomic design of vehicle interiors has been established for many years. Most use cases focus on various aspects of static driving configurations. But several dynamical occupant tasks must be evaluated for new vehicle concepts in addition. Because of the task complexity these tests are still performed in physical mock-ups. Over the past years new DHM technologies have supported evaluating dynamic ergonomics of interior designs in digital mock-ups more efficient. Nevertheless, there are still simulation aspects to be improved for proper industrial applications. This paper presents the recent development progress on knowledge-based motion simulation techniques using motion capture data and DHM prediction methods. The focus was put on a large variability of motions in the database, more user control on the simulated motions and functions for collision avoidance. Based on adjustable mock-ups, a range of ingress and egress motions into a truck and a passenger car were systematically measured taking various positions of vehicle components like steps, doors, pillars and roofs into account. These motion takes were reconstructed and annotated by DHMs and stored in a database. A new simulation tool was developed which use the database to predict motions in virtual environments. The GUI provides a range of motion components subjected to various motion data and simulation methods. These components can be combined to create a cumulative motion. In addition, the intersection frames of consecutive components can be controlled by user-defined postures or tasks. Smooth transitions are supported by specific truncating and sewing up consecutive motions. In addition, the tool got new functions to consider collision avoidance during simulation. First, characteristic parameters (door angle) are extracted from the environment and used to find corresponding collision-free motions in the database. Second, specific geometric constraints avoid collisions at key frames. Applying both functions supports qualitative motion strategy changes and quantitative body positions to cope with collision situations. The tool development is accompanied by user evaluations with respect to usability and prediction capabilities.These identified open issues to be solved and pushed the tool further forward to a productive level.

show abstract

Section: Methodsmentioning

confidence: 99%