English

FPGA-Based In-Vivo Calcium Image Decoding for Closed-Loop Feedback Applications

Image and Video Processing 2023-04-18 v2

Abstract

Miniaturized calcium imaging is an emerging neural recording technique that has been widely used for monitoring neural activity on a large scale at a specific brain region of rats or mice. Most existing calcium-image analysis pipelines operate offline. This results in long processing latency, making it difficult to realize closed-loop feedback stimulation for brain research. In recent work, we have proposed an FPGA-based real-time calcium image processing pipeline for closed-loop feedback applications. It can perform real-time calcium image motion correction, enhancement, fast trace extraction, and real-time decoding from extracted traces. Here, we extend this work by proposing a variety of neural network based methods for real-time decoding and evaluate the tradeoff among these decoding methods and accelerator designs. We introduced the implementation of the neural network based decoders on the FPGA, and showed their speedup against the implementation on the ARM processor. Our FPGA implementation enables the real-time calcium image decoding with sub-ms processing latency for closed-loop feedback applications.

Keywords

Cite

@article{arxiv.2212.04736,
  title  = {FPGA-Based In-Vivo Calcium Image Decoding for Closed-Loop Feedback Applications},
  author = {Zhe Chen and Garrett J. Blair and Chengdi Cao and Jim Zhou and Daniel Aharoni and Peyman Golshani and Hugh T. Blair and Jason Cong},
  journal= {arXiv preprint arXiv:2212.04736},
  year   = {2023}
}

Comments

11 pages, 15 figures

R2 v1 2026-06-28T07:27:25.869Z