Abstract
Humans are remarkably efficent at recognizing objects. Understanding how the brain performs object recognition has been challenging. Our understanding has been advanced substantially in recent years with the development of multivariate decoding methods. Most start-of-the-art decoding procedures, make use of the ‘mean’ neural activation to extract object category information, which overlooks temporal variability in the signals. Here, we studied category-related information in 30 mathematically distinct features from electroencephalography (EEG) across three independent and highly-varied datasets using multivariate decoding. While the event-related potential (ERP) components of N1 and P2a were among the most informative features, the informative original signal samples and Wavelet coefficients, selected through principal component analysis, outperformed them. The four mentioned informative features showed more pronounced decoding in the Theta frequency band, which has been suggested to support feed-forward processing of visual information in the brain. Correlational analyses showed that the features, which were most informative about object categories, could predict participants’ behavioral performance (reaction time) more accurately than the less informative features. These results suggest a new approach for studying how the human brain encodes object category information and how we can read them out more optimally to investigate the temporal dynamics of the neural code. The codes are available online at https://osf.io/wbvpn/.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
Revised all sections after receiving reviews