English

SCONE: A Practical, Constraint-Aware Plug-in for Latent Encoding in Learned DNA Storage

Machine Learning 2026-02-09 v1

Abstract

DNA storage has matured from concept to practical stage, yet its integration with neural compression pipelines remains inefficient. Early DNA encoders applied redundancy-heavy constraint layers atop raw binary data - workable but primitive. Recent neural codecs compress data into learned latent representations with rich statistical structure, yet still convert these latents to DNA via naive binary-to-quaternary transcoding, discarding the entropy model's optimization. This mismatch undermines compression efficiency and complicates the encoding stack. A plug-in module that collapses latent compression and DNA encoding into a single step. SCONE performs quaternary arithmetic coding directly on the latent space in DNA bases. Its Constraint-Aware Adaptive Coding module dynamically steers the entropy encoder's learned probability distribution to enforce biochemical constraints - Guanine-Cytosine (GC) balance and homopolymer suppression - deterministically during encoding, eliminating post-hoc correction. The design preserves full reversibility and exploits the hyperprior model's learned priors without modification. Experiments show SCONE achieves near-perfect constraint satisfaction with negligible computational overhead (<2% latency), establishing a latent-agnostic interface for end-to-end DNA-compatible learned codecs.

Keywords

Cite

@article{arxiv.2602.06157,
  title  = {SCONE: A Practical, Constraint-Aware Plug-in for Latent Encoding in Learned DNA Storage},
  author = {Cihan Ruan and Lebin Zhou and Rongduo Han and Linyi Han and Bingqing Zhao and Chenchen Zhu and Wei Jiang and Wei Wang and Nam Ling},
  journal= {arXiv preprint arXiv:2602.06157},
  year   = {2026}
}
R2 v1 2026-07-01T10:23:20.458Z