Shift-invariant rank-(L, L, 1, 1) BTD with 3D spatial pooling and orthonormalization: Application to multi-subject fMRI data

• Published in: Biomedical signal processing and control Vol. 92; p. 106058
• Main Authors: Kuang, Li-Dan, Zhang, Hao-Peng, Zhu, Hao, He, Shiming, Li, Wenjun, Gui, Yan, Zhang, Jin, Zhang, Jianming
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.06.2024
• Subjects: Block term decomposition (BTD); Orthonormality; Shift-invariance; Spatiotemporal variability; Tensor decomposition; Weighted spatial pooling; Tensor decomposition; Shift-invariance; Weighted spatial pooling; Block term decomposition (BTD); Orthonormality; Spatiotemporal variability
• ISSN: 1746-8094; 1746-8108
• DOI: 10.1016/j.bspc.2024.106058

•A novel shift-invariant rank-(L, L, 1, 1) BTD with 3D spatial pooling and orthonormalization for multi-subject fMRI data separation.•Two loading matrices of shared SMs, shared TCs, subject-specific time delays and strengths can be decomposed by the proposed method.•The proposed 3D weighted spatial pooling preprocessing compresses and smooths multi-subject fMRI data, and assigns a higher weight to in-brain voxels but a lower weight to out-brain voxels, which reduces the size and improves robustness to noise.•To deal with the high spatiotemporal variability, the proposed methods relaxes the rank-(L, L, 1, 1) BTD model of the reduced fMRI data by incorporating temporal shift-invariance and spatial orthonormality constraints. The rank-(L, L, 1, 1) block term decomposition (BTD) model shows better separation performance for multi-subject fMRI data by preserving the high-way structure of fMRI data than canonical polyadic decomposition (CPD). However, multi-subject fMRI data are noisy and have high spatiotemporal variability. To address these limitations, this paper proposes a novel 3D weighted spatial pooling preprocessing that compresses and smooths multi-subject fMRI data and assigns a higher weight to in-brain voxels but a lower weight to out-brain voxels. This strategy not only largely reduces the size of spatial images but also improves the robustness to noise. Furthermore, to address the high spatiotemporal variability, the rank-(L, L, 1, 1) BTD model of the reduced fMRI data is relaxed by incorporating temporal shift-invariance and spatial orthonormality constraints to extract pooled multi-subject shared spatial maps, shared time courses, subject-specific time delays and intensities. Finally, multi-subject intact shared spatial maps are obtained based on shift-invariant rank-(L, L, 1, 1) BTD of intact fMRI data. The simulated and experimental fMRI data experiments both verify that the proposed method achieves better separation performance and stronger robustness to noise than rank-(L, L, 1, 1) BTD with a spatial orthonormality constraint and a method combining independent component analysis and shift-invariant CPD. Moreover, the proposed method with 3D spatial pooling yields better separation performance than that with 2D spatial pooling, because 3D spatial pooling preserves refined voxels, thereby retaining more information of adjacent slices.