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Main Authors: Khandelwal, Shashwat, Petri-Koenig, Jakoba, Preußer, Thomas B., Blott, Michaela, Shanker, Shreejith
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.20810
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author Khandelwal, Shashwat
Petri-Koenig, Jakoba
Preußer, Thomas B.
Blott, Michaela
Shanker, Shreejith
author_facet Khandelwal, Shashwat
Petri-Koenig, Jakoba
Preußer, Thomas B.
Blott, Michaela
Shanker, Shreejith
contents Recurrent neural networks (RNNs), particularly LSTMs, are effective for time-series tasks like sentiment analysis and short-term stock prediction. However, their computational complexity poses challenges for real-time deployment in resource constrained environments. While FPGAs offer a promising platform for energy-efficient AI acceleration, existing tools mainly target feed-forward networks, and LSTM acceleration typically requires full custom implementation. In this paper, we address this gap by leveraging the open-source and extensible FINN framework to enable the generalized deployment of LSTMs on FPGAs. Specifically, we leverage the Scan operator from the Open Neural Network Exchange (ONNX) specification to model the recurrent nature of LSTM computations, enabling support for mixed quantisation within them and functional verification of LSTM-based models. Furthermore, we introduce custom transformations within the FINN compiler to map the quantised ONNX computation graph to hardware blocks from the HLS kernel library of the FINN compiler and Vitis HLS. We validate the proposed tool-flow by training a quantised ConvLSTM model for a mid-price stock prediction task using the widely used dataset and generating a corresponding hardware IP of the model using our flow, targeting the XCZU7EV device. We show that the generated quantised ConvLSTM accelerator through our flow achieves a balance between performance (latency) and resource consumption, while matching (or bettering) inference accuracy of state-of-the-art models with reduced precision. We believe that the generalisable nature of the proposed flow will pave the way for resource-efficient RNN accelerator designs on FPGAs.
format Preprint
id arxiv_https___arxiv_org_abs_2506_20810
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle FINN-GL: Generalized Mixed-Precision Extensions for FPGA-Accelerated LSTMs
Khandelwal, Shashwat
Petri-Koenig, Jakoba
Preußer, Thomas B.
Blott, Michaela
Shanker, Shreejith
Machine Learning
Artificial Intelligence
Hardware Architecture
Signal Processing
Recurrent neural networks (RNNs), particularly LSTMs, are effective for time-series tasks like sentiment analysis and short-term stock prediction. However, their computational complexity poses challenges for real-time deployment in resource constrained environments. While FPGAs offer a promising platform for energy-efficient AI acceleration, existing tools mainly target feed-forward networks, and LSTM acceleration typically requires full custom implementation. In this paper, we address this gap by leveraging the open-source and extensible FINN framework to enable the generalized deployment of LSTMs on FPGAs. Specifically, we leverage the Scan operator from the Open Neural Network Exchange (ONNX) specification to model the recurrent nature of LSTM computations, enabling support for mixed quantisation within them and functional verification of LSTM-based models. Furthermore, we introduce custom transformations within the FINN compiler to map the quantised ONNX computation graph to hardware blocks from the HLS kernel library of the FINN compiler and Vitis HLS. We validate the proposed tool-flow by training a quantised ConvLSTM model for a mid-price stock prediction task using the widely used dataset and generating a corresponding hardware IP of the model using our flow, targeting the XCZU7EV device. We show that the generated quantised ConvLSTM accelerator through our flow achieves a balance between performance (latency) and resource consumption, while matching (or bettering) inference accuracy of state-of-the-art models with reduced precision. We believe that the generalisable nature of the proposed flow will pave the way for resource-efficient RNN accelerator designs on FPGAs.
title FINN-GL: Generalized Mixed-Precision Extensions for FPGA-Accelerated LSTMs
topic Machine Learning
Artificial Intelligence
Hardware Architecture
Signal Processing
url https://arxiv.org/abs/2506.20810