Correcting variance and polarity indeterminacies of extracted components by canonical polyadic decomposition
Hao, Y., Li, H., Hu, G., Zhao, W., & Cong, F. (2024). Correcting variance and polarity indeterminacies of extracted components by canonical polyadic decomposition. Brain-Apparatus Communication, 3(1), Article 2403477. https://doi.org/10.1080/27706710.2024.2403477
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Brain-Apparatus CommunicationDate
2024Copyright
© 2024 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group
Background
Back-projection has been used to correct the variance and polarity indeterminacies for the independent component analysis. The variance and polarity of the components are essential features of neuroscience studies.
Objective
This work extends the back-projection theory to canonical polyadic decomposition (CPD) for high-order tensors, aiming to correct the variance and polarity indeterminacies of the components extracted by CPD.
Methods
The tensor is reshaped into a matrix and decomposed using a suitable blind source separation algorithm. Subsequently, the coefficients are projected using back-projection theory, and other factor matrices are computed through a series of singular value decompositions of the back-projection matrix.
Results
By applying this method, the energy and polarity of each component are determined, effectively correcting the variance and polarity indeterminacies in CPD. The proposed method was validated using simulated tensor data and resting-state fMRI data.
Conclusion
Our proposed back-projection method for high-order tensors effectively corrects variance and polarity indeterminacies in CPD, offering a precise solution for calculating the energy and polarity required to extract meaningful features from neuroimaging data.
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Publisher
Taylor & FrancisISSN Search the Publication Forum
2770-6710Keywords
Publication in research information system
https://converis.jyu.fi/converis/portal/detail/Publication/243225341
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Additional information about funding
This work was supported by the National Natural Science Foundation of China [grant numbers 91748105 & 81471742], the Science and Technology Planning Project of Liaoning Provincial [grant numbers 2022JH2/10700002 and 2021JH1/10400049], and the scholarship from China Scholarship Council (No. 202306060039).License
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