A Real-Time Neural Representation via Algorithm-Hardware Synergy for Sparse-View CT Reconstruction

Sparse-view computed tomography (SVCT) is an advancement in computed tomography (CT) technology that aims to reduce the radiation dose during imaging. Reconstructing high-quality images from sparse-view (SV) projections is an ill-posed inverse problem. Recently, implicit neural representations (INRs...

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Veröffentlicht in:	IEEE transaction on neural networks and learning systems Jg. PP; S. 1 - 13
Hauptverfasser:	Li, Xin, Wan, Haochuan, Long, Kangjie, Wu, Qing, Du, Chenhe, Su, Ying, Luo, Zhe, Lou, Xin, Zhang, Yuyao
Format:	Journal Article
Sprache:	Englisch
Veröffentlicht:	United States IEEE 04.11.2025
Schlagworte:	Computed tomography Computed tomography (CT) reconstruction Encoding Feature extraction Image reconstruction implicit neural representation (INR) Inference algorithms Magnetic resonance imaging Neural radiance field real-time reconstruction Real-time systems Rendering (computer graphics) software-hardware synergy sparse-view CT Training
ISSN:	2162-237X, 2162-2388, 2162-2388
Online-Zugang:	Volltext
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Zusammenfassung:	Sparse-view computed tomography (SVCT) is an advancement in computed tomography (CT) technology that aims to reduce the radiation dose during imaging. Reconstructing high-quality images from sparse-view (SV) projections is an ill-posed inverse problem. Recently, implicit neural representations (INRs) as a self-supervised paradigm for solving underdetermined inverse problems have demonstrated excellent performance in SVCT reconstruction. However, since INR-based approaches rely on subject-specific training, they require a significant investment of time to optimize from scratch. Consequently, previous INR methods have not been able to meet the requisite timeliness of reconstruction. In our work, we propose RTSyner, an algorithm-hardware collaboration framework that facilitates the real-time efficiency of CT reconstruction. On the algorithmic side, we introduce an efficient coordinate-based feature module that exploits the local latent features as a positional external condition, leveraging the limited structural information of corrupted images derived from the sensory domain. By fusing latent features and coordinate information, the model learns a neural representation of the final tomographic image. On the hardware side, we design a dedicated hardware architecture with a customized algorithm flow to improve reconstruction speed and reduce power consumption. Furthermore, we improve the efficiency of model inference through model quantization, which also facilitates the subsequent deployment of hardware. Our extensive experimental results demonstrate that the RTSyner based on neural representation has achieved real-time SVCT reconstruction through the synergistic acceleration of the algorithm and hardware. We further explore its application potential via volume reconstructions under more complex acquisition geometries.
Bibliographie:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
ISSN:	2162-237X 2162-2388 2162-2388
DOI:	10.1109/TNNLS.2025.3626038