A Hybrid Neural Network for High-Throughput Attosecond Resolution Single-shot X-ray Pulse Characterization

Abstract: As scientific facilities transition toward high-throughput, data-intensive experiments, there is a growing need for real-time computing at the edge to support autonomous decision-making and minimize data transmission bottlenecks. Department of Energy (DOE) initiatives emphasize the development of heterogeneous computing architectures that integrate ML models with specialized hardware such as FPGAs, GPUs, and embedded systems to meet the demands of next-generation experiments. These advances are critical for facilities such as X-ray free-electron lasers (XFELs), where high-repetition-rate experiments produce terabyte-scale datasets, requiring real-time analysis and control. To address this challenge, we introduce DCIFR, a deep learning framework optimized for edge processing and high-speed X-ray diagnostics at SLAC's Linac Coherent Light Source (LCLS). DCIFR leverages a hybrid neural architecture, combining convolutional neural networks (CNNs), bidirectional long short-term memory (BiLSTM) networks, and residual neural networks (ResNets) to denoise sinograms, classify X-ray sub-spikes, and extract phase separation with attosecond precision. The model achieves a phase extraction accuracy of 0.04652 radians (29.6 attoseconds at 1.2 um streaking wavelength) with inference latencies of 168.3 us and throughput exceeding 10kHz. Designed for deployment on heterogeneous architectures, DCIFR reduces computational overhead and supports future AI-driven feedback loops for ultrafast experiments. This work demonstrates the potential of edge AI and hardware acceleration to drive scalable, autonomous data analysis in next-generation DOE scientific facilities.