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Low-Rank Tucker-2 Model for Multi-Subject fMRI Data Decomposition with Spatial Sparsity Constraint
- Publication Year :
- 2022
- Publisher :
- Institute of Electrical and Electronics Engineers (IEEE), 2022.
-
Abstract
- Tucker decomposition can provide an intuitive summary to understand brain function by decomposing multi-subject fMRI data into a core tensor and multiple factor matrices, and was mostly used to extract functional connectivity patterns across time/subjects using orthogonality constraints. However, these algorithms are unsuitable for extracting common spatial and temporal patterns across subjects due to distinct characteristics such as high-level noise. Motivated by a successful application of Tucker decomposition to image denoising and the intrinsic sparsity of spatial activations in fMRI, we propose a low-rank Tucker-2 model with spatial sparsity constraint to analyze multi-subject fMRI data. More precisely, we propose to impose a sparsity constraint on spatial maps by using an lp norm (0
- Subjects :
- Rank (linear algebra)
Computer science
Matrix norm
low-rank
matrix decomposition
symbols.namesake
toiminnallinen magneettikuvaus
Orthogonality
tensors
Tensor (intrinsic definition)
Kronecker delta
Tucker decomposition
Humans
Electrical and Electronic Engineering
core tensor
sparsity constraint
Radiological and Ultrasound Technology
business.industry
signaalinkäsittely
feature extraction
sparse matrices
Brain
Pattern recognition
brain modeling
Magnetic Resonance Imaging
functional magnetic resonance imaging
Computer Science Applications
Constraint (information theory)
data models
symbols
Noise (video)
Artificial intelligence
business
multi-subject fMRI data
Software
Algorithms
Subjects
Details
- Language :
- English
- Database :
- OpenAIRE
- Accession number :
- edsair.doi.dedup.....98be2f086269f59403ac0dcc01fc416b