English

The Dual-Stream Transformer: Channelized Architecture for Interpretable Language Modeling

Computation and Language 2026-03-10 v1 Artificial Intelligence Machine Learning

Abstract

Standard transformers entangle all computation in a single residual stream, obscuring which components perform which functions. We introduce the Dual-Stream Transformer, which decomposes the residual stream into two functionally distinct components: a token stream updated by attention and a context stream updated by feed-forward networks. Information flow between attention heads is controlled through a hierarchy of mixing strategies, from fully independent (maximum interpretability) to dense (standard transformer behavior). This design exposes a tunable tradeoff between interpretability and performance. We measure this tradeoff on language modeling tasks at 29M parameters. Fully independent head mixing increases validation loss by 8\% relative to dense baselines. The recommended Kronecker mixing strategy, which permits scalar communication between heads while preserving within-head structure, costs only 2.5\%. All configurations maintain functional generation under attention amplification (scaling logits by factors up to 16 at inference time), with degradation ranging from 16\% to 27\%. This robustness suggests the architectures learn discrete algorithms that operate independently of soft probabilistic mixing. The architecture provides a foundation for interpretable language models where internal structure is exposed by design. \footnote{This work was partially supported by DARPA Contract HR001125C0302.}

Keywords

Cite

@article{arxiv.2603.07461,
  title  = {The Dual-Stream Transformer: Channelized Architecture for Interpretable Language Modeling},
  author = {J. Clayton Kerce and Alexis Fox},
  journal= {arXiv preprint arXiv:2603.07461},
  year   = {2026}
}
R2 v1 2026-07-01T11:08:53.880Z