English

Polynomial Surrogate Training for Differentiable Ternary Logic Gate Networks

Machine Learning 2026-03-03 v1 Artificial Intelligence Logic in Computer Science

Abstract

Differentiable logic gate networks (DLGNs) learn compact, interpretable Boolean circuits via gradient-based training, but all existing variants are restricted to the 16 two-input binary gates. Extending DLGNs to Ternary Kleene K3K_3 logic and training DTLGNs where the UNKNOWN state enables principled abstention under uncertainty is desirable. However, the support set of potential gates per neuron explodes to 19,68319{,}683, making the established softmax-over-gates training approach intractable. We introduce Polynomial Surrogate Training (PST), which represents each ternary neuron as a degree-(2,2)(2,2) polynomial with 9 learnable coefficients (a 2,187×2{,}187\times parameter reduction) and prove that the gap between the trained network and its discretized logic circuit is bounded by a data-independent commitment loss that vanishes at convergence. Scaling experiments from 48K to 512K neurons on CIFAR-10 demonstrate that this hardening gap contracts with overparameterization. Ternary networks train 22-3×3\times faster than binary DLGNs and discover true ternary gates that are functionally diverse. On synthetic and tabular tasks we find that the UNKNOWN output acts as a Bayes-optimal uncertainty proxy, enabling selective prediction in which ternary circuits surpass binary accuracy once low-confidence predictions are filtered. More broadly, PST establishes a general polynomial-surrogate methodology whose parameterization cost grows only quadratically with logic valence, opening the door to many-valued differentiable logic.

Keywords

Cite

@article{arxiv.2603.00302,
  title  = {Polynomial Surrogate Training for Differentiable Ternary Logic Gate Networks},
  author = {Sai Sandeep Damera and Ryan Matheu and Aniruddh G. Puranic and John S. Baras},
  journal= {arXiv preprint arXiv:2603.00302},
  year   = {2026}
}

Comments

28 pages, 13 figures. Submitted to 3rd International Conference on Neuro-Symbolic Systems (NeuS) 2026

R2 v1 2026-07-01T10:56:36.607Z