As genome sequencing is finding utility in a wide variety of domains beyond the confines of traditional medical settings, its computational pipeline faces two significant challenges. First, the creation of up to 0.5 GB of data per minute imposes substantial communication and storage overheads. Second, the sequencing pipeline is bottlenecked at the basecalling step, consuming >40% of genome analysis time. A range of proposals have attempted to address these challenges, with limited success. We propose to address these challenges with a Compute-in-Memory Basecalling Accelerator (CiMBA), the first embedded (∼25mm2) accelerator capable of real-time, on-device basecalling, coupled with AnaLog (AL)-Dorado, a new family of analog focused basecalling DNNs. Our resulting hardware/software co-design greatly reduces data communication overhead, is capable of a throughput of 4.77 million bases per second, 24x that required for real-time operation, and achieves 17x/27x power/area efficiency over the best prior basecalling embedded accelerator while maintaining a high accuracy comparable to state-of-the-art software basecallers.
@article{arxiv.2504.07298,
title = {CiMBA: Accelerating Genome Sequencing through On-Device Basecalling via Compute-in-Memory},
author = {William Andrew Simon and Irem Boybat and Riselda Kodra and Elena Ferro and Gagandeep Singh and Mohammed Alser and Shubham Jain and Hsinyu Tsai and Geoffrey W. Burr and Onur Mutlu and Abu Sebastian},
journal= {arXiv preprint arXiv:2504.07298},
year = {2025}
}
Comments
Accepted to IEEE Transactions on Parallel and Distributed Systems