Neural Field
Neural fields represent data as continuous functions parameterized by neural networks, aiming to efficiently and accurately model complex, high-dimensional data. Current research focuses on improving training speed and efficiency through novel initialization schemes and architectural designs, such as sinusoidal neural fields and multi-resolution approaches incorporating techniques like diffusion nets and Fourier features. These advancements are impacting diverse fields, enabling applications in 3D scene reconstruction, medical imaging (e.g., cardiac modeling, photoacoustic tomography), fluid dynamics simulation, and robotics, by offering flexible, continuous representations that surpass traditional methods in accuracy and efficiency.
Papers
Neural Acoustic Context Field: Rendering Realistic Room Impulse Response With Neural Fields
Susan Liang, Chao Huang, Yapeng Tian, Anurag Kumar, Chenliang Xu
SHACIRA: Scalable HAsh-grid Compression for Implicit Neural Representations
Sharath Girish, Abhinav Shrivastava, Kamal Gupta
NeuRBF: A Neural Fields Representation with Adaptive Radial Basis Functions
Zhang Chen, Zhong Li, Liangchen Song, Lele Chen, Jingyi Yu, Junsong Yuan, Yi Xu
CoNeS: Conditional neural fields with shift modulation for multi-sequence MRI translation
Yunjie Chen, Marius Staring, Olaf M. Neve, Stephan R. Romeijn, Erik F. Hensen, Berit M. Verbist, Jelmer M. Wolterink, Qian Tao
ResFields: Residual Neural Fields for Spatiotemporal Signals
Marko Mihajlovic, Sergey Prokudin, Marc Pollefeys, Siyu Tang