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Main Authors: Tew, Hwa Hui, Loo, Junn Yong, Tan, Yee-Fan, Tang, Xinyu, Ombao, Hernando, Noman, Fuad, Phan, Raphael C. -W., Ting, Chee-Ming
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.20822
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author Tew, Hwa Hui
Loo, Junn Yong
Tan, Yee-Fan
Tang, Xinyu
Ombao, Hernando
Noman, Fuad
Phan, Raphael C. -W.
Ting, Chee-Ming
author_facet Tew, Hwa Hui
Loo, Junn Yong
Tan, Yee-Fan
Tang, Xinyu
Ombao, Hernando
Noman, Fuad
Phan, Raphael C. -W.
Ting, Chee-Ming
contents Functional Magnetic Resonance Imaging (fMRI) is an advanced neuroimaging method that enables in-depth analysis of brain activity by measuring dynamic changes in the blood oxygenation level-dependent (BOLD) signals. However, the resource-intensive nature of fMRI data acquisition limits the availability of high-fidelity samples required for data-driven brain analysis models. While modern generative models can synthesize fMRI data, they often underperform because they overlook the complex non-stationarity and nonlinear BOLD dynamics. To address these challenges, we introduce T2I-Diff, an fMRI generation framework that leverages time-frequency representation of BOLD signals and classifier-free denoising diffusion. Specifically, our framework first converts BOLD signals into windowed spectrograms via a time-dependent Fourier transform, capturing both the underlying temporal dynamics and spectral evolution. Subsequently, a classifier-free diffusion model is trained to generate class-conditioned frequency spectrograms, which are then reverted to BOLD signals via inverse Fourier transforms. Finally, we validate the efficacy of our approach by demonstrating improved accuracy and generalization in downstream fMRI-based brain network classification.
format Preprint
id arxiv_https___arxiv_org_abs_2509_20822
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle T2I-Diff: fMRI Signal Generation via Time-Frequency Image Transform and Classifier-Free Denoising Diffusion Models
Tew, Hwa Hui
Loo, Junn Yong
Tan, Yee-Fan
Tang, Xinyu
Ombao, Hernando
Noman, Fuad
Phan, Raphael C. -W.
Ting, Chee-Ming
Machine Learning
Functional Magnetic Resonance Imaging (fMRI) is an advanced neuroimaging method that enables in-depth analysis of brain activity by measuring dynamic changes in the blood oxygenation level-dependent (BOLD) signals. However, the resource-intensive nature of fMRI data acquisition limits the availability of high-fidelity samples required for data-driven brain analysis models. While modern generative models can synthesize fMRI data, they often underperform because they overlook the complex non-stationarity and nonlinear BOLD dynamics. To address these challenges, we introduce T2I-Diff, an fMRI generation framework that leverages time-frequency representation of BOLD signals and classifier-free denoising diffusion. Specifically, our framework first converts BOLD signals into windowed spectrograms via a time-dependent Fourier transform, capturing both the underlying temporal dynamics and spectral evolution. Subsequently, a classifier-free diffusion model is trained to generate class-conditioned frequency spectrograms, which are then reverted to BOLD signals via inverse Fourier transforms. Finally, we validate the efficacy of our approach by demonstrating improved accuracy and generalization in downstream fMRI-based brain network classification.
title T2I-Diff: fMRI Signal Generation via Time-Frequency Image Transform and Classifier-Free Denoising Diffusion Models
topic Machine Learning
url https://arxiv.org/abs/2509.20822