Logo Logo
Hilfe
Hilfe
Switch Language to English

Ott, Felix; Rügamer, David ORCID logoORCID: https://orcid.org/0000-0002-8772-9202; Heublein, Lucas; Bischl, Bernd ORCID logoORCID: https://orcid.org/0000-0001-6002-6980 und Mutschler, Christopher (2022): Joint Classification and Trajectory Regression of Online Handwriting using a Multi-Task Learning Approach. 2022 IEEE/CVF Winter Conference on Applications of Computer Vision (WACV), Waikoloa, Hawaii, 4-8 January 2022. In: 2022 IEEE Winter Conference on Applications of Computer Vision : 4-8 January 2022, Waikoloa, Hawaii : proceedings, Piscataway, NJ: IEEE. S. 1244-1254

Volltext auf 'Open Access LMU' nicht verfügbar.

Abstract

Multivariate Time Series (MTS) classification is important in various applications such as signature verification, person identification, and motion recognition. In deep learning these classification tasks are usually learned using the cross-entropy loss. A related yet different task is predicting trajectories observed as MTS. Important use cases include handwriting reconstruction, shape analysis, and human pose estimation. The goal is to align an arbitrary dimensional time series with its ground truth as accurately as possible while reducing the error in the prediction with a distance loss and the variance with a similarity loss. Although learning both losses with Multi-Task Learning (MTL) helps to improve trajectory alignment, learning often remains difficult as both tasks are contradictory. We propose a novel neural network architecture for MTL that notably improves the MTS classification and trajectory regression performance in online handwriting (OnHW) recognition. We achieve this by jointly learning the cross-entropy loss in combination with distance and similarity losses. On an OnHW task of handwritten characters with multivariate inertial and visual data inputs we are able to achieve crucial improvements (lower error with less variance) of trajectory prediction while still improving the character classification accuracy in comparison to models trained on the individual tasks.

Dokument bearbeiten Dokument bearbeiten