TY - CHAP
T1 - A Knowledge-Driven Tool for Automatic Activity Dataset Annotation
AU - Azkune, Gorka
AU - Almeida, Aitor
AU - López-de-ipiña, Diego
AU - Chen, Liming
PY - 2015
Y1 - 2015
N2 - Human activity recognition has become a very important research topic, due to its multiple applications in areas such as pervasive computing, surveillance, context-aware computing, ambient assistive living or social robotics. For activity recognition approaches to be properly developed and tested, annotated datasets are a key resource. However, few research works deal with activity annotation methods. In this paper, we describe a knowledge-driven approach to annotate activity datasets automatically. Minimal activity models have to be provided to the tool, which uses a novel algorithm to annotate datasets. Minimal activity models specify action patterns. Those actions are directly linked to sensor activations, which can appear in the dataset in varied orders and with interleaved actions that are not in the pattern itself. The presented algorithm finds those patterns and annotates activities accordingly. Obtained results confirm the reliability and robustness of the approach in several experiments involving noisy and changing activity executions.
AB - Human activity recognition has become a very important research topic, due to its multiple applications in areas such as pervasive computing, surveillance, context-aware computing, ambient assistive living or social robotics. For activity recognition approaches to be properly developed and tested, annotated datasets are a key resource. However, few research works deal with activity annotation methods. In this paper, we describe a knowledge-driven approach to annotate activity datasets automatically. Minimal activity models have to be provided to the tool, which uses a novel algorithm to annotate datasets. Minimal activity models specify action patterns. Those actions are directly linked to sensor activations, which can appear in the dataset in varied orders and with interleaved actions that are not in the pattern itself. The presented algorithm finds those patterns and annotates activities accordingly. Obtained results confirm the reliability and robustness of the approach in several experiments involving noisy and changing activity executions.
U2 - 10.1007/978-3-319-11313-5_52
DO - 10.1007/978-3-319-11313-5_52
M3 - Chapter
SN - 978-3-319-11312-8
VL - 322
T3 - Intelligent Systems'2014
SP - 593
EP - 604
BT - Intelligent Systems'2014. Advances in Intelligent Systems and Computing
ER -