FTerViT: Fully Ternary Vision Transformer
Abstract
Ternary Vision Transformers offer substantial model compression, however state-of-the-art methods only ternarize the encoder layers, leaving patch embeddings, LayerNorm parameters, and classifier heads in full precision. In compact models targeting resource-constrained processors, such as microcontrollers, these remaining full-precision components determine the total memory footprint, severely limiting deployment efficiency and on-device feasibility. In this work, we introduce a fully ternarized Vision Transformer in which \emph{all} weight matrices and normalization parameters are ternarized (FTerViT). To this end, we introduce two novel operators : TernaryBitConv2d with per-channel scaling for patch embedding and TernaryLayerNorm. FTerViT is trained using knowledge distillation, followed by a lightweight quantization-aware recovery phase. Our ternary W2A8 DeiT-III-S at 384384 resolution achieves 82.43\% ImageNet-1K top-1 at 6.09\,MB (15 compression, 2.42\,pp vs.\ FP32), outperforming prior ternary ViTs methods up to 8 pp. Finally, we demonstrate the first implementation of ternary vision transformers on a dual cores XTensa LX7 microcontroller inside the ESP32-S3 system-on-chip. By deploying FTerViT-Small (based on DeiT-III-Small at 224224 resolution, 5.81\,MB), we achieve 79.64\% ImageNet-1K top-1 accuracy.
Keywords
Cite
@article{arxiv.2605.21171,
title = {FTerViT: Fully Ternary Vision Transformer},
author = {Szymon Ruciński and Pietro Bonazzi and Engin Türetken and Simon Narduzzi and Michele Magno and Nadim Maamari},
journal= {arXiv preprint arXiv:2605.21171},
year = {2026}
}
Comments
Preprint